Title of Invention	A METHOD AND APPARATUS FOR REFRIGERATING A PRESSURIZED LIQUIFIED NATURAL GAS
Abstract	The present invention relates to a method for refrigerating liquefied natural gas under pressure (1), comprising a first step wherein the LNG (1) is cooled, expanded and separated (1) in a first base fraction (4) which is collected, and (b) a first top fraction (3) which is heated, compressed in a compressor(Kl) and cooled into a first compressed fraction (5) which is collected; a second compressed fraction (6) is drawn from the fiiel gas (5), cooled then mixed with the cooled and expanded LNG (1). The invention is characterized in that it comprises a second step wherein the second compressed fraction (6) is compressed and cooled, and a flux is (8) drawn and cooled, expanded and introduced in the compressor (Kl). The invention also describes other embodiments. (Fig. 2)

Title of Invention

A METHOD AND APPARATUS FOR REFRIGERATING A PRESSURIZED LIQUIFIED NATURAL GAS

Abstract

The present invention relates to a method for refrigerating liquefied natural gas under pressure (1), comprising a first step wherein the LNG (1) is cooled, expanded and separated (1) in a first base fraction (4) which is collected, and (b) a first top fraction (3) which is heated, compressed in a compressor(Kl) and cooled into a first compressed fraction (5) which is collected; a second compressed fraction (6) is drawn from the fiiel gas (5), cooled then mixed with the cooled and expanded LNG (1). The invention is characterized in that it comprises a second step wherein the second compressed fraction (6) is compressed and cooled, and a flux is (8) drawn and cooled, expanded and introduced in the compressor (Kl). The invention also describes other embodiments. (Fig. 2)

Full Text	The present invention relates, in general, and according to a first of its aspects, to the gas industry and, in particular, to a method for refrigerating pressurized gas containing methane and C2 and higher hydrocarbons, so as to separate then. BACKGROUND OF INVENTION US 3,616,652 (Dl) discloses in view of its figure, a process for refrigerating a liquefied natural gas 6 comprising a step in which the liquefied natural gas is expanded in a turbine 7, then a step in which the extended liquefied natural gas is splitted in a flask 11 into a relatively more volatile first top fraction 13 and into a relatively less volatile bottom fraction 12. The bottom fraction 12 is collected. The first top fraction 13 is heated in exchangers 9,14,15,5, then compressed 16 before being cooled in refrigerant 17 to constitute a first compressed combustible gas fraction. This fraction is compressed into a second compressor 18 to provide a third compressed fraction, the cooled into a refrigerant 19 before being split at separation 21 into a compressed fraction 23 and into a fifth compressed fraction 25,27. The fourth compressed fraction 23 is cooled and expanded in turbine 22. A part of the fifth fraction is cooled and mixed at point 28 with the expanded liquefied natural gas flux. More specifically, the invention relates according to its first aspect, to a method for refiigerating a pressurized liquefied gas containing methane and C2 and higher hydrocarbons comprising a first step (I) in which (la) said pressurized liquefied natural gas is expanded to provide an expanded liquefied natural gas stream, in which step (lb) said expanded liquefied natural gas is split in a relatively more volatile first top fraction and a relatively less volatile first bottom fraction, in which step (Ic) the first bottom fraction consisting of refrigerated liquefied natural gas is collected, in which step (Id) the first top fraction is heated, compressed in a first compressor and cooled to provide a first fiiel gas compressed fraction which is collected, in which step (le) there is tapped off from the first compressed fraction a second compressed fraction which is then cooled, then mixed with the expanded liquefied natural gas stream. Refrigeration method of this type are well known to those skilled in the art and have been in use for many years. The method for refrigerating liquefied natural gas (LNG) according to the above preamble is used in the known way with a view of eliminating the nitrogen present sometimes in large quantities in the natural gas. In this case, the fuel gas obtained using this method is nitrogen-rich, whereas the refrigerated liquefied natural gas is nitrogen-depleted. Installations for liquefying natural gas have well-defined technical characteristics and limits dictated by the capacity of the production elements of which they are made. In consequence, an installation producing liquefied natural gas is limited by its maximum production capacity, under normal operating conditions. The only way to increase production consists in building a new production unit. Given the cost that such an investment represents, it is necessary to make sure that the desired increase in production will be lasting, so as to make the cost easier to amortize. At the present time there is no way to increase production of a liquefied natural gas production unit, even temporarily, when this unit is running at full capacity, without resorting to heavy and expensive investment consisting in building another production unit. The liquefied natural gas (LNG) production capacity depends essentially on the power of the compressors used to refrigerate and liquefy the natural gas. This being the case, a first object of the invention is to propose a method, in other respects in accordance with the generic definition given in the above preamble, that allows the capacity of an LNG production unit to be increased without having to resort to building another LNG production unit, and which is essentially characterized in that the method comprises a second step (II) in which step (Ila) the second compressed fraction is compressed in a second compressor coupled to an expansion turbine to provide a third compressed fraction, in which step (lib) the ^ .gF-'3—- third compressed fraction is cooled, then split into a fourth compressed fraction and a fifth compressed fraction, in which step (lie) the fourth compressed fraction is cooled and expanded in the expansion turbine coupled to the second compressor to provide an expanded fraction which is then heated, then introduced into a medium-pressure first stage of the compressor, and in which step (lid) the fifth compressed fraction is cooled, then mixed with the expanded liquefied natural gas stream. A first merit of the invention is that it has discovered that a production unit running at 100% capacity, producing a certain delivery of liquefied natural gas at a temperature of -IGCC and at a pressure close to 50 bar, all other operating parameters being constant, can have its delivery, and therefore its production, increased only by increasing the temperature at which the liquefied natural gas is produced. However, the LNG is stored at about -160 °C at low pressure (under 1.1 bar absolute), and an increase in its storage temperature would lead to an increase in its storage pressure, and this represents prohibitive costs, and above all difficulties with transport, because of the very large quantities of LNG produced. In consequence, it is common practice for the LNG to be prepared at a temperature close to -160°C prior to its being stored. A second merit of the invention is that it presents an elegant solution to these limits on production by using a method for refrigerating LNG that can be adapted to an already-existing method for producing LNG, not requiring the use of significant financial and concrete means to implement this method. This solution comprises the production, by an already-existing LNG production ^ unit, of LNG at a temperature above about -160°C, then refrigerating it to about -160°C using the method according to the invention. A third merit of the invention is that it has modified a known method in accordance with the preamble above for refrigerating nitrogen-rich liquefied natural gas and that it has allowed it to be used both with nitrogen-rich LNG and with nitrogen-depleted LNG. In the latter instance, the fuel gas obtained using this method contains very little nitrogen, and therefore has a composition close to that of the nitrogen-depleted liquefied natural gas. According to a first aspect of the method of the invention, the expanded liquefied natural gas stream can be split, prior to step (lb), into a second top fraction and a second bottom fraction, the second top fraction can be heated, then introduced into the first compressor in an intermediate medium-pressure second stage between the medium-pressure first stage and a low-pressure stage, and the second bottom fraction can be split into the first top fraction and the first bottom fraction. According to the first aspect of the method of the invention, each compression step can be followed by a cooling step. According to a second of its aspects, the invention relates to a refrigerated liquefied natural gas and a fuel gas obtained by any one of the above-defined methods. According to a third of its aspects, the invention relates to an installation for refrigerating a pressurized liquefied natural gas containing methane and C2 and higher hydrocarbons, comprising means for carrying out a first step (I) in which step (la) said ^ pressurized liquefied natural gas (1) is expanded to provide an expanded liquefied natural gas stream, in which step (lb) said expanded liquefied natural gas is split into a relatively more volatile first top fraction and a relatively less volatile first bottom fraction, in which step (Ic) the first bottom fraction consisting of refrigerated liquefied natural gas is collected, in which step (Id) the first top fraction is heated, compressed in a first compressor and cooled to provide a first fuel gas compressed fraction which is collected, in which step (le) there is tapped off from the first compressed fraction a second compressed fraction which is then cooled, then mixed with the expanded liquefied natural gas stream, characterized in that the installation comprises means for carrying out a second step (II) in which step (Ila) the second compressed fraction is compressed in a second compressor coupled to an expansion turbine to provide a third compressed fraction, in which step (lib) the third compressed fraction is cooled, then split into a fourth compressed fraction and a fifth compressed fraction, in which step (lie) the fourth compressed fraction is cooled and expanded in the expansion turbine coupled to the second compressor to provide an expanded fraction which is then heated, then introduced into a medium-pressure first stage of the compressor, and in which step (lid) the fifth compressed fraction is cooled, then mixed with the expanded liquefied natural gas stream. According to a fii?^t alternative form according to its ""•VWf-TMV ■I-...,;. '■ ...■■:.■,,.■,. ;, ,.,j^,, , , third aspect, the invention relates to an installation comprising means for splitting the expanded liquefied natural gas stream, prior to step (lb) , into a second top fraction and a second bottom fraction, in that the installation comprises means for heating, then introducing the second top fraction into the first compressor in an intermediate medium-pressure second stage between the medium-pressure first stage and a ^ low-pressure stage, and in that it comprises means for splitting the second bottom fraction into the first top fraction and the first bottom fraction. According to a first embodiment according to its third aspect, the invention relates to an installation in which the first top fraction and the first bottom fraction are separated in a first separating vessel. According to a second embodiment according to its third aspect, the invention relates to an installation in which the first top fraction and the first bottom fraction are separated in a distillation column. According to one embodiment according to the first alternative form of its third aspect, the invention relates to an installation in which the expanded liquefied natural gas stream can be split into the second top fraction and the second bottom fraction in a second separating vessel. According to its second embodiment according to its third aspect, the invention relates to an installation in which the distillation column comprises at least one lateral and/or column-bottom reboiler,, in that liquid tapped off a plate of the distillation column passing through said reboiler is heated in a second heat exchanger, then reintroduced into the distillation column at a stage below said plate, and in that the expanded liquefied natural gas stream is cooled in said second heat exchanger. According to a third embodiment according to its third aspect, the invention relates to an installation in which the cooling of the first top fraction and of the expanded fraction, and the heating of the fourth compressed fraction and of the fifth compressed fraction take place in one and the same first heat exchanger. ^ -.^-^?— According to the first alternative form according to its third aspect, the invention relates to an installation in which the second top fraction is heated in the first heat exchanger. The invention will be better understood and other objects, features, details and advantages thereof will become more clearly apparent in the course of the description which follows with reference to the attached schematic drawings given solely by way of nonlimiting example and in which: figure 1 depicts a functional block diagram of an installation for liquefying natural gas according to one embodiment of the prior art; figure 2 depicts a functional block diagram of an installation for removing nitrogen from liquefied natural gas according to a first embodiment of the prior art; figure 3 depicts a functional block diagram of an V installation for removing nitrogen from liquefied natural gas according to a second embodiment of the prior art; figures 4, 5, 6 and 7 depict functional block diagrams^ of installations possibly for removing nitrogen from liquefied natural gas according to some preferred embodiments of the invention. stands for stands for stands for stands for stands for In these seven figures, there are the symbols "FC", which stands for "flow controller", "GT" which stands for "gas turbine", "GE" which "electric generator", "LC" which "liquid level controller", "PC" which "pressure controller", "SC" which "speed controller" and "TC" which "temperature controller". For clarity and succinctness, the pipes used in the installations of figures 1 to 7 will be identified by ; .- 8 - , the same reference symbols as the gaseous fractions passing through them. Referring to figure 1, the installation depicted is intended, in a known way, to treat a dried, desulfurized and decarbonated natural gas 100, to obtain liquefied natural gas 1, generally available at a temperature below -120°C. This installation for liquefying LNG has two independent cooling circuits. A first cooling circuit 101, corresponding a propane cycle, makes it possible to obtain primary cooling to about -30°C in an exchanger E3 by expanding and vaporizing liquid propane. The heated and expanded propane vapor is then compressed in a second compressor K2, then the compressed gas 102 obtained is then cooled and liquefied in water coolers 103, 104 and 105. A second cooling circuit 106, corresponding in general to a cycle operating on a mixture of nitrogen, methane, ethane and propane, allows significant cooling of the natural gas that is to be treated, to obtain liquefied natural gas 1. The heat transfer fluid present in the second cooling cycle is compressed in a third compressor K3 and cooled in water exchangers 118 and 119 and is then cooled in a water cooler 114 to obtain a fluid 107. The latter is then cooled and liquefied in the exchanger E3 to provide a cooled and liquefied stream 108. The latter is then split into a vapor phase 109 and a liquid phase 110 which are both introduced into the lower part of a cryogenic exchanger 111. After cooling, the liquid phase 110 then leaves the exchanger 111 to be expanded in a turbine X2 coupled to an electric generator. The expanded fluid 112 is then introduced into the cryogenic exchanger 111 above its lower part, where it is used to cool the fluids passing through the lower part of the exchanger, by being sprayed onto the pipes conveying the fluids that are to /O be cooled, using spray booms. The vapor phase 109 passes through the lower part of the cryogenic exchanger 111 where it is cooled and liquefied, and is then cooled further by passing through an upper part of the cryogenic exchanger 111. Finally, this cooled and liquefied fraction 109 is expanded in a valve 115, then used to cool the fluids passing through the upper part of the cryogenic exchanger 111, by spraying it onto the pipes conveying the fluids that are to be cooled. The liquid coolants sprayed inside the cryogenic exchanger 111 are then collected at the bottom of the exchanger to provide the stream 106 which is sent to the compressor K3. The dried, desulfurized and decarbonated natural gas 100 is cooled in a propane heat exchanger 113 and then subjected to a drying treatment, which may, for example, involve passing it over a molecular sieve, for example made of zeolite, and to a demercurization treatment, for example by passing it over a silver foam or over any other mercury trap, in a chamber 116 to provide a purified natural gas 117. The latter is then cooled and partially liquefied in the heat exchanger E3, passes through the lower part, then through the upper part of the cryogenic exchanger 111 to provide a liquefied natural gas 1. The latter is customarily obtained at a temperature below -120°C. Referring now to figure 2, the installation depicted is intended, in the known way, to treat a nitrogen-rich liquefied natural gas 1 to obtain, on the one hand, a nitrogen-depleted cooled liquefied natural gas 4 and, on the other hand, a first compressed fraction 5 which is a nitrogen-rich compressed fuel gas. The LNG 1 is first of all expanded and cooled in an expansion turbine X3 which is regulated by a flow controller controlling the flow of LNG passing through the pipe 1, then is expanded and cooled again in a // —to valve 18 the opening of which is dependent on the pressure of the LNG leaving the compressor X3, to provide an expanded liquefied natural gas stream 2. The latter is then split into a relatively more volatile first top fraction 3 and a relatively less volatile bottom fraction 4 in a vessel VI. The first bottom fraction 4 consisting of cooled liquefied natural gas is collected and pumped in a pump PI, passes through a valve 19, the opening of which is regulated by a level controller controlling the level of liquid in the bottom of the vessel VI, to then leave the installation and go for storage. The first top fraction 3 is heated in a first heat exchanger El and is then introduced into a low-pressure stage 15 of a compressor Kl coupled to a gas turbine GT. This compressor Kl comprises a plurality of compression stages 15, 14, 11 and 30, at progressively higher pressures, and a plurality of water coolers 31, 32, 33 and 34. After each compression stage, the compressed gases are cooled by passing them through a heat exchanger, preferably a water heat exchanger. The first top fraction 3, at the end of the compression and cooling steps, provides the nitrogen-rich compressed fuel gas 5. This fuel gas is then collected and leaves the installation. A small part of the fuel gas 5 which corresponds to a stream 6 is tapped off. This stream 6 is cooled in the exchanger El, giving up its heat to the first top fraction 3, to yield a cooled stream 22. This cooled stream 22 then flows through a valve 23 the opening of which is controlled by a flow controller at the outlet of the exchanger E2. The stream 22 is finally mixed with the expanded liquefied natural gas stream 2. Referring now to figure 3, the installation depicted is intended, in the known way, to treat a nitrogen-rich liquefied natural gas 1 to obtain, on the one hand, a /=? 3ri • installation, the separating vessel VI has been replaced by a distillation column Cl and a heat exchanger E2. The LNG 1 is first of all expanded and cooled in an expansion turbine X3 the speed of which is controlled by a flow controller controlling the flow of LNG through the pipe 1, and is then cooled in the heat exchanger E2 to provide a cooled stream 20. The latter passes through a valve 21, the opening of which is controlled by a pressure controller on the pipe 20, upstream of said valve 21, to provide an expanded liquefied natural gas stream 2. The expanded liquefied natural gas stream 2 is then split into a relatively more volatile first top fraction 3 and a relatively less volatile first bottom fraction 4 in the column Cl. The first bottom fraction 4 consisting of cooled liquefied natural gas is collected and pumped in a p^imp PI, passes through a valve 19 the opening of which is controlled by a level controller controlling the level of liquid in the bottom of the vessel VI, and then leaves the installation and goes for storage. The column Cl comprises a column bottom reboiler 16 which uses liquid contained on a plate 17. The stream passing through the reboiler 16 is heated in the heat exchanger E2 and then introduced into the bottom of the column Cl. The first top fraction 3 follows the same treatment as set out in figure 2, to obtain a first compressed gas fraction 5, which is a nitrogen-rich compressed fuel gas, and a second compressed fraction 6 which is a tapped-off compressed fuel gas fraction. Similarly, the latter fraction is heated in the exchanger El to yield a cooled stream 22. This stream 22 is also mixed with the expanded liquefied natural gas stream 2. /3 ^.^2 a cooled stream 22. This stream 22 is also mixed with the expanded liquefied natural gas stream 2. Referring now to figure 4, the installation depicted is intended, with the aid of a device according to the method of the invention, to treat a nitrogen-rich liquefied natural gas 1 to obtain, on the one hand, a nitrogen-depleted and cooled liquefied natural gas 4 and, on the other hand, a nitrogen-rich compressed fuel gas 5. This installation comprises elements in common with figure 3, particularly the expansion and cooling of the LNG 1 to obtain the expanded LNG stream 2. Likewise, the splitting into the first top fraction 3 and the first bottom fraction 4 is performed in a similar way in the column CI. Finally, the fuel gas stream 5 is obtained, as before, by successive compression and cooling operations. Unlike the method set out in figure 3, a second compressed fraction 6, tapped off the first compressed gas fraction 5 is fed to a compressor XKl coupled to an expansion turbine XI to obtain a third compressed fraction 7. This fraction is cooled in a water cooler 24, then split into a fourth compressed fraction 8 and a fifth compressed fraction 9. The fourth compressed fraction 8 is cooled in the heat exchanger" El to provide a fraction 25 which is expanded in the turbine XI. The turbine XI supplies an expanded stream 10 which is heated in the exchanger El to give a heated expanded stream 26. This heated expanded stream 26 is introduced into a medium-pressure stage 11 of the compressor Kl. The fifth compressed fraction 9 is cooled in the heat exchanger El to provide a fraction 22 which is expanded in a valve 23 then mixed with the expanded LNG fraction 2. /i The expander XI comprises an inlet guide valve 27 making it possible, by varying the angle at which the stream 25 is introduced to the blades of the turbine XI, to vary the speed at which the latter rotates, and therefore to cause the power delivered to the compressor XKl to vary. Referring now to figure 5, the installation depicted is intended, with the aid of a device according to the method of the invention, to treat a liquefied natural gas 1, preferably nitrogen rich, to obtain, on the one hand, a cooled and nitrogen-depleted liquefied natural gas 4 and, on the other hand, a nitrogen-rich compressed fuel gas 5, when the liquefied natural gas 1 contains nitrogen. This installation comprises elements in common with figure 4, particularly the production, by a distillation column CI, of a first top fraction 3 and of a first bottom fraction 4. Similarly, the first top fraction 3 is compressed in a compressor Kl and cooled in coolers 31 - 34 to obtain a first compressed fraction 5. A second tapped-off fraction 6 is tapped off the first compressed fraction 5 to be compressed in a compressor XKl coupled to an expansion turbine XI, which at outlet produces a third compressed fraction 7. The latter is split into a fourth compressed fraction 8 and a fifth compressed fraction 9. The fourth compressed fraction 8 is cooled in the heat exchanger El to provide a fraction 25 which is expanded in the turbine XI. The turbine XI supplies an expanded stream 10 which is heated in the exchanger El to give a heated expanded stream 26. This heated expanded stream 26 is introduced into a medium-pressure stage 11 of the compressor Kl. The fifth compressed fraction 9 is cooled in the heat exchanger El to provide a fraction 22 which is expanded /f in a valve 23, then mixed with the expanded LNG fraction 2. The expander XI comprises an inlet guide valve 27 whose purpose was defined in the description of figure 4. Unlike figure 4, the installation depicted in figure 5 further comprises a separating vessel V2 in which the expanded natural gas stream 2 is split into a second top fraction 12 and a second bottom fraction 13. The second top fraction 12 is heated in the exchanger El then introduced into a medium-pressure stage 14 of the compressor Kl, at a pressure that it is intermediate between the inlet pressure of the low pressure stage 15 and that of the medium-pressure stage 11. The second bottom fraction 13 is cooled in an exchanger E2 to produce a cooled LNG fraction 20. This last fraction is expanded and cooled in a valve 28 to produce an expanded and cooled LNG fraction 29. The opening of the valve 28 is controlled by a level controller controlling the level of liquid contained in the vessel V2. The stream 29 is then introduced into the column CI where it is split into the first top fraction 3 and the first bottom fraction 4. As indicated during the description of figure 4, the column CI comprises a reboiler 16 which taps off liquid contained on a plate 17 of the column CI to heat it in the exchanger E2 by heat exchange with the stream 13, and introduce it into the bottom of the column. Likewise, the first bottom fraction 4 is pumped by a pump PI and passes through a valve 19 the opening of which is controlled by a level controller controlling the level of liquid present in the bottom of the column CI. '^ /i Referring now to figure 6, the installation depicted is intended, with the aid of a device according to the method of the invention, to treat a liquefied natural gas 1, preferably nitrogen-depleted, to obtain, on the one hand, a cooled and nitrogen-depleted liquefied natural gas 4 and, on the other hand, a nitrogen-rich compressed fuel gas 5, when an LNG 1 rich in nitrogen is used. This installation comprises elements common to figure 2 and figures 4 and 5. In a simplified way, figure 6 is structurally similar to figure 4 except that the column CI has been replaced by a separating vessel VI, and the exchanger E2 has been omitted, because there is no reboiler when using a separating vessel. The expanded LNG stream 2 is therefore introduced directly into the separating vessel VI to be split into a first top fraction 3 and a first bottom fraction 4. Replacing the column CI with the vessel VI does not alter the sequence of steps of the method as described for figure 5. By contrast, because the vessel VI does not have such good separation performance as the column CI, the cooled LNG 4 will normally contain more nitrogen when a device according to figure 6 is used than when a device according to figure 5 is used. Of course, the LNG 1 used in both instances is physically and chemically identical, and contains at least a little nitrogen. Referring to figure 7, the installation depicted is intended, with the aid of a device according to the method of the invention, to treat a liquefied natural gas 1, preferably nitrogen-depleted, to obtain, on the one hand, a cooled liquefied natural gas 4 and, on the other hand, a compressed fuel gas 5. M- This installation comprises elements common to figure 2 and to figures 4, 5 and 6. In a simplified way, figure 7 is structurally similar to figure 5 except that the column CI has been replaced by a separating vessel VI, and the exchanger E2 has been omitted, because there is no reboiler when using a separating vessel. The expanded LNG stream 2 is therefore introduced directly into the separating vessel V2 to be split into a second top fraction 12 and a second bottom fraction 13. The second top fraction 12 is heated in an exchanger El then introduced into a compressor Kl at an intermediate medium-pressure stage 14, between a low-pressure stage 15 and a medium-pressure stage 11, in the same way as described for figure 5. Replacing the column CI with the vessel VI does not alter the sequence of steps of the method as described for figure 5. By contrast, because the vessel VI does not have such good separating performance as the column CI, the cooled LNG 4 will normally contain more nitrogen when a device according to figure 6 is used than when a device according to figure 5 is used. Of course, in order to allow for a valid comparison, the LNG 1 used in both cases is physically and chemically identical. In order to allow a material assessment of the performance of an installation operating according to a method according to the invention, numerical examples are now given, for illustrative rather than limitative purposes. These examples are given on the basis of two different natural gases "A" and "B", the composition of which is given below in table 1: /r --i:?- Component Natural L gas A Natural Gas B Molar composition (%) Composition by mass (%) Molar composition (%) Composition by mass (%) Nitrogen 0.100 0.155 3.960 6.127 Methane Ethane 4.500 ,7.510 5.360 8.902 Propane 2.500 6.118 1.845 4.493 i-Butane 0.600 1.935 0.290 0.931 n-Butane 0.900 2.903 0.470 1.509 Total 100.000 100.000 100.000 100.000 Table 1 These gases are deliberately free of C5 and higher hydrocarbons, so as not to make the calculations any more complicated. The other operating conditions are identical and as follows (the reference numerals relate to fig. 1): temperature of the wet natural gas 100: 37°C pressure of the wet natural gas 100: 54 bar pre-cooling by the cooler 113 prior to drying: 23°C temperature of the dry gas after it has passed through chamber 116: 23.5°C pressure of the dry gas: 51 bar temperature of the cooling water: 30°C temperature at the exit of CTie water exchanger: 37°C temperature at which propane condenses: 47°C efficiency of the centrifugal compressors Kl, K2 and K3: 82% efficiency of the expansion turbine X2: 85% efficiency of the axial compressor XKl: 86% power on a GE6 shaft run: 31570 kW power on a GE7 shaft run: 63140 kW power on a GE5D shaft run: 24000 kW /f The power on a shaft run represents the power available on a shaft of a general electric gas turbine reference GE5D, GE6 and GE7. Turbines of this type are coupled to the compressors Kl, K2 and K3 depicted in figures 1-7. The deliveries of natural gas to be liquefied will be chosen to saturate the available power on the shaft runs. The following three cases are envisioned (for a liquefication method described in figure 1): Use for driving one GE6 turbine and one GE7 turbine, which "corresponds to a delivery of LNG produced at -160°C of about 3 million tonnes per year. Use for driving two GE7 turbines, which correspondsto a delivery of LNG produced at -160°C of about 4 million tonnes per year. Use for driving three GE7 turbines, which corrBsponds to a delivery of LNG produced at -160°C of about 6 million tonnes per year. One of the ways for easily calculating the influence of a parameter without going into the details of a method is that of the idea of Theoretical Work associated with the idea of Exergy. The theoretical work that has to be given to a system in order to cause it to change from state 1 to state 2 is given by the following equation: Wl-2 = TO X (SI - S2) - (HI - H2) With: TO SI S2 HI H2 Wl-2: theoretical work (kJ/kg) temperature at which heat is rejected (K) entropy in state 1 (kJ/(K.kg)) entropy in state 2 (kJ/(K.kg)) enthalpy in state 1 (kJ/kg) enthalpy in state 2 (kJ/kg) M —±s— In this instance, the rejection temperature will be taken as being equal to 310.15 K (37°C). State 1 will be the natural gas at 37°C and 51 bar and state 2 will be the LNG at a temperature T2 and at 50 bar. Table 2 below shows the change in theoretical work to liquefy natural gases A and B according to the temperature of the LNG leaving the liquefication method. When the power of the refrigeration compressors is constant, the reduction in theoretical work results in a possible increase in the capacity of the liquefication cycle. Temperature of the LNG 1 (°C) Natural Gas A Theoretical work (kJ/kg) Theoretical work (%) Possible capacity (%) -130 356.63 71.19 140.46 -135 376.93 75.25 132.90 -140 398.45 79.54 125.72 -145 421.57 84.16 118.82 -150 446.24 89.08 112.26 -155 472.64 94.35 105.99 -160 500.93 100.00 100.00 'k'kifirififie'kic'k'k'^ Natural Gas B -130 355.89 71.35 140.16 -135 376.04 75.39 132.65 -140 397.43 79.67 125.51 -145 420.23 84.24 118.70 -150 444.56 89.12 112.21 -155 470.74 94.37 105.97 -160 498.82 100.00 100.00 Table 2 It can be seen that the figures obtained with the gases A and B are very similar. The possible increase in capacity is about 1.14% per °C of temperature of the LNG 1 obtained at the exit of the liquef ication unit set out in figure 1. The capacity Cl for a temperature Tl of the LNG produced can be expressed as a function of the capacity CO at the temperature TO, using the following equation: i/ CI = CO X 1.0114 (Tl - TO) With: CI CO Tl T2 capacity to produce LNG at Tl (kg/h) capacity to produce reference LNG at TO (kg/h) LNG production temperature (°C) reference LNG production temperature (°C) As a result, at -140°C, the capacity of the LNG production unit is 125.5% of its capacity at -160°C, which is a considerable difference. The actual work of an LNG production unit will obviously be dependent upon the method chosen. The method depicted in figure 1, which is known by the name of MCR®, is a well known method widely used and developed by the company APCI. This method is used here in a special way that gives it very good performance: the propane cycle has 4 stages and the MCR (multiple component refrigerant, stream 106, fig. 1) refrigeration and propane refrigeration (stream 102, fig. 1) takes place in the heat exchanger E3, which is a brazed aluminum plate-type exchanger. The results obtained are set out table 3: (PCS^ Temperature of the LNG 1 (°C) Natural Gas A Actual work (kJ/kg) Actual work (%) Possible capacity (%) -130 702.77 72.23 138.45 -135 739.93 76.05 131.50 -140 781.25 , 80.29 124.54 -145 820.56 84.33 118.58 -150 867.88 89.20 112.11 -155 917.44 94.29 106.05 -160 972.99 100.00 100.00 **•••■•••■•* Natural Gas B -130 688.86 71.24 140.37 -135 728.22 75.31 132.78 -140 772.16 79.86 125.23 -145 814.34 84.22 118.74 -150 861.75 89.12 •1. A. £^ m £m J. -155 94.37 105.97 -160 100.00 100.00 Table 3 It can be seen that these results per^fectly corroborate those obtained using the theoretical work calculations and set out in table 1. The efficiency of the liquefication method can be calculated from the actual work and from the theoretical work. The latter is roughly constant and is round about 51.5%, as can be seen from the results given in table 4: Temperature of the LNG 1 (°C) Natural Gas A Theoretical work (kJ/kg) Actual work (%) Efficiency (%) -130 356.63 702.77 50.75 -135 376.93 739.93 50.94 -140 398.45 781.25 51.00 -145 421.57 820.56 51.38 -150 446.24 867.88 51.42 -155 472.64 917.44 51.52 -160 500.93 972.99 51.48 **■■■■■■■•**** Natural Gas B -130 355.89 688.86 51.66 -135 376.04 728.22 51.64 -140 397.43 772.16 51.47 -145 420.23 814.34 51.60 -150 444.56 861.75 51.59 Table 4 This result is particularly satisfying. The user of the method will always be assured of making best use of the liquefication method, regardless of the chosen temperature at which the LNG is produced. It can also be seen that the composition of the natural gas that is to be liquefied has no importance. Thus, the novel use of the known liquefication method makes it possible to increase the temperature of the LNG 1 obtained at the outlet of the production unit while at the same time allowing a substantial increase in the quantity produced, which may range as high as about 40% at -130°C. The LNG 1 obtained at the outlet of the production unit described above for figure 1, can have its nitrogen removed in a denitrogenation unit such as depicted in figure 2 or in figure 3. This nitrogen-removal operation is needed when the natural gas extracted from the source contains nitrogen in relatively high proportions, for example upwards of 0.100 mol% to about 5 to 10 mol%. M produce LNG 1, and "3 GE7" corresponds to the use of 3 turbines: Units 1 GE7 + 1 GE6 2 6E7 3 6E7 LNG 1 Temperature °C -150 -150 -150 Flow rate kg/h 406665 542219 813330 Cooled LNG 4 Flow rate kg/h 368990 491985 737980 Specific lower heat value kJ/kg 48412 48412 48412 Nitrogen content mol% 1.38 1.38 1.38 Production of LNG 4, lower heat value GJ/h % 17864 100 23818 100 35727 100 Fuel gas 5 Flow rate kg/h 37676 50235 75352 Specific lower heat value kJ/kg 27492 27492 27492 Production of fuel gas 5, specific lower heat value GJ/h 1036 1381 2072 Denitrogenation unit Power of compressor Kl kW 7037 9383 14074 Performance Specific power of production of LNG kJ/kg 1019 1019 1019 Ratio of power of Kl/production of LNG 4 0.0210 0.0210 0.0210 Table 5 The installation depicted schematically in figure 3 is an LNG denitrogenation unit with a denitrogenation column. Replacing the flash in the vessel VI with a denitrogenation column CI allows an appreciable improvement in the efficiency with which the nitrogen contained in the LNG 1 is extracted. In this installation, the LNG 1 at -145.5°C is expanded to 5 bar in the expansion hydraulic turbine X3, then is cooled from -146.2°C to -157'C in the exchanger E2 by exchange of heat with the liquid flowing through the ^ column bottom reboiler 16 to obtain an expanded and cooled LNG stream 20. The stream 20 undergoes a second expansion to 1.15 bar in a valve 21 and feeds into the denitrogenation column CI as a mixture with the LNG 22 from the partial recycling of the compressed fuel gas 5. At the bottom of the denitrogenation column CI, the LNG contains 0.06% nitrogen, whereas the nitrogen content of the LNG using a final flash was 1.38% (fig. 2 and table 5). This column bottom LNG is pumped by a pump PI and represents a cooled LNG fraction 4 which is sent for storage. The fuel gas 3, which is the first top fraction from the column CI, is heated to -75°C in the exchanger El, then compressed to 29 bar in the compressor Kl and cooled by the water coolers 31 - 34 to provide a compressed fuel gas 5. A stream 6, which represents 23% of the compressed gas 5 is recycled to the column CI after the heating of the stream 3 in the exchanger El. The fuel gas produced, which represents 1032 GJ/h in the case of the use of one GE6 turbine and one GE7 turbine, is roughly identical in terms of total calorific value to that of the final flash unit of fig. 2. The same is true when using more substantial LNG production units (2 or 3 GE7s). The use of the technique of removing nitrogen in a denitrogenation column has made it possible to increase by 5.62% the capacity of the liquefication process, for a minor on-cost. It must be understood that it is the combination of use of a denitrogenation column CI and of the recycling of fuel gas which leads to this highly encouraging result. U.f ^ 26 - The power of the fuel gas compressor Kl depends on the size of the unit. It will be: 8087 kW for an LNG unit using 1 GE6 combined with 1 GE / r 10783 kW for an LNG unit using 2 GE7s, 16174 kW an LNG unit using 3 GE7s. The powers of these machines and the start-up problems mean that it is desirable to use a gas turbine to drive the fuel gas compressor Kl. The other performance data for the method are given in table 6: Units 1 GE7 + 1 GE6 2 GE7 3 GE7 LNG 1 Temperature "C -145.5 -145.5 -145.5 Flow rate kg/h 428175 570899 856350 Cooled LNG 4 Flow rate kg/h 381659 508877 763318 Specific lower heat value kJ/kg 49434 49434 49434 Nitrogen content mol% 0.06 0.06 0.06 Production of LNG 4, lower heat value GJ/h % 18867 105.62 25156 105.62 37734 105.62 Fuel gas 5 Flow rate kg/h 46517 62023 93034 Specific lower heat value kJ/kg 22191 22191 22191 Production of fuel gas 5, specific lower heat value GJ/h 1032 1376 2065 Denitrogenation unit Power of compressor Kl kW 8087 10783 16174 Performance Specific power of production of LNG kJ/kg 995 995 995 Ratio of power of Kl/production of LNG 4 0.0201 0.0201 0.0201 Additional production of LNG kg/h GJ/h 12669 1003 16892 1338 25338 2007 Table 6 One of the main problems encountered in industrial installations for treating and liquefying gases is ^ - 27 ■ ■ related in particular to the optimum use of the compression apparatus which represents a significant investment, both in terms of initial purchase and in terms of power consumption. Indeed, compressors requiring power of the order of several tens of thousand kW need to be reliable and to be able to be used under conditions of optimum efficiency over the broadest possible range of loads. Of course, this comment also applies to the means used to run them, these means here usually being gas turbines, because of the commercially available range of powers. Gas turbines in order to be efficient, need to be used at full capacity. Consider the example of a denitrogenation unit operating according to any one of the embodiments described in figures 2 and 3. The gas turbine driving the compressor Kl needs to have a maximum power tailored to the power required by the compressor, so as to obtain the most favorable possible compression efficiency. However, a gas turbine may find itself operating under conditions such that the power delivered to the compressor is markedly below its capacity. This is the case for example when a GE5d gas turbine, with a power of 24000 kw, is coupled to the compressor Kl when nitrogen is being removed by final flash or by separation in a column. The consequence of this underuse of the turbine is a reduction in the energy efficiency of the compression stage relative to the power consumption of the turbine. Of course, the power of the compressor Kl varies according to the size of the unit, as was explained above. Thus, the use of a GE5d turbine makes it possible to enjoy excess power amounting to: 15913 kW for an LNG unit using 1 GE6 turbine associated with 1 GE7 turbine. Jil > 28 - 13217 kW for an LNG unit using 2 GET turbines, 7826 kW for an LNG unit using 3 GE7 turbines. It is therefore desirable to use this excess available power. The method according to the invention in particular proposes to use all of the available power to drive the compressor Kl. The method according to the invention also makes it possible to increase the temperature at the outlet of the liquefication method, to obtain the LNG stream 1, and to use the excess power available on the gas turbine driving Kl to cool the LNG to -160°C. Furthermore, the method according to the invention makes it possible,^ because of the possibility of increasing the temperature of the LNG 1 produced for example according to the APCI method, to increase the flow rate of LNG cooled to -160°C substantially, to an extent which in some cases may be by about 40%. The method of the invention has the merit that it can be implemented easily, because of the simplicity of the means needed to embody it. One embodiment according to the method of the invention, employing a denitrogenation column CI, is set out in figure 4, described above. For the same turbine power driving the compressor Kl, the operating conditions will depend on the capacity of the natural gas liquefication unit. An LNG 1 is produced at -140.5°C using the APCI method dgpTcted in figure 1. This method is implemented using two GE7 gas turbines to drive the compressors K2 and K3. The LNG 1 enters the installation set out in figure 4. It is expanded to 6.1 bar in the expansion hydraulic turbine X3 driving an electric generator, then cooled from -141.2 to -157 "C in a heat exchanger s& E2 by exchange of heat with a liquid passing through a column bottom reboiler 16 to provide a cooled LNG 21. The latter is expanded to 1.15 bar in a valve 21 to obtain an expanded stream 2 which is fed into a column CI as a mixture with a stream 22, as indicated above in the description of the figures. The LNG stream 4, tapped off at the bottom of the column CI, contains 0.00% nitrogen. The fuel gas 3 is heated to -34 "C in the exchanger El, then is compressed to 29 bar in the compressor Kl to feed into a fuel gas network. A first difference compared with the known method stems from the amount of compressed gas 6 tapped off the fuel gas stream 5: this is now up to about 73%. This compressed gas 6 is compressed to 38.2 bar in the compressor XKl to provide a fraction 7. The latter is cooled to 37°C in a water exchanger 24 then split into two flows 8 and 9. The flow 8, which is the larger flow, representing 70% of the stream 7, is cooled to -82°C by passing through the exchanger El, then is fed to the turbine XI, coupled to the compressor XKl. The expanded stream leaving the turbine 10, at a pressure of 9 bar and a temperature of -138°C, is heated in the exchanger El to 32 °C then fed into the compressor Kl at a medium-pressure stage 11 which is the third stage. The flow 9, which is the smaller flow, representing 30% of the stream 7, is liquefied and cooled to -160°C and returns to the denitrogenation column 01. The fuel gas produced represents 1400 GJ/h, and is identical in total calorific value to that of the final flash unit. The use of the denitrogenation technique and of the method of the invention has made it possible M^ to increase by 11.74% the capacity of the liquefication sequence, for a reasonable on-cost. It must be understood that it is the combination of the use of a denitrogenation column, of the recycling of the compressed fuel gas and of the expansion turbine cycle which leads to this highly surprising result. For the other sizes of LNG production unit, the results are given in table 7: Units 1 6E7 + 1 6E6 2 GE7 3 GE7 LNG 1 Temperature 'C -138.5 -140.5 -143.5 Flow rate kg/h 462359 602827 875470 Cooled LNG 4 Flow rate kg/h 413619 537874 781438 Specific lower heat value kj/kg 49479 49479 49479 Nitrogen content mol% 0.00 0.00 0.00 Production of LNG 4, lower heat value GJ/h % 20465 114.57 26613 111.74 38661 108.21 Fuel gas 5 Flow rate kg/h 48713 64994 94055 Specific lower heat value kJ/kg 21008 21535 21521 Production of fuel gas 5, specific lower heat value GJ/h 1023 1400 2024 Denitrogenation unit Power of compressor Kl kW 23963 23970 23990 Power of expander XI kW 2835 2058 1175 Performance Specific power of production of LNG kJ/kg 1056 1030 983 Ratio of power of Kl/production of LNG 4 0.0213 0.0208 0.0199 Additional production of LNG kg/h GJ/h 44629 2602 45889 2795 43458 2934 Table 7 It can be seen that the increases in capacity are by: - 14.2% for an LNG unit using one GE7 turbine associated with one GE6 turbine, 11.7% for an LNG unit using two GE7 turbines. M 8.21% for an LNG unit using three GE7 turbines. The method according to the invention also has a considerable benefit in regulating the amount of fuel gas produced. Indeed, it is now possible to have sustained production of fuel gas, as shown in a numerical example in table 8 below: Units 2 GE7 LNG 1 Temperature °c -135 Flow rate kg/h 641176 Cooled LNG 4 Flow rate kg/h 546088 Specific lower heat value kJ/kg 49454 Nitrogen content mol% 0.00 Production of LNG 4, lower heat value GJ/h % 27006 113.39 Fuel gas 5 Flow rate kg/h 95092 Specific lower heat value kJ/kg 29361 Production of fuel gas 5, specific lower heat value GJ/h 2792 Denitrogenation unit Power of compressor Kl kW 23900 Power of expander XI kW 802 Performance Specific power of production of LNG 4 kJ/kg 1014 Ratio of power of Kl/production of LNG 4 0.0205 Additional production of LNG kg/h GJ/h 54103 3188 Table 8 It can be seen that when the amount of fuel gas rises from 1400 to 2800 GJ/h, it is then possible to increase the capacity by 13.39%, that is to say that 1.65% increase in capacity (13.39% minus 11.74%) are due to the increase in production of fuel gas. Another embodiment according to the method of the invention, employing a denitrogenation column 01, is set out in figure 5 described above. Unlike in figure 4, this embodiment employs a separating vessel V2. The LNG 1, of composition "B" obtained at -140.5°C under a pressure of 48.0 bar with a flow rate of 33294 kmol/h, is expanded to 6.1 bar and minus 141.25°C in the hydraulic turbine X3, then expanded again to 5.1 bar and -143.39°C in the valve IB, to provide the expanded stream 2. The stream 2 (33294 kmol/h) is mixed with the stream 35 (2600 kmol/h) to obtain the stream 36 (35894 kmol/h) at -146.55°C. The stream 35 is made up of 42.97% nitrogen, 57.02% methane and 0.01% ethane. The stream 36, which is made up of 6.79% nitrogen, 85.83% methane, 4.97% ethane, 1.71% propane, 0.27% isobutane and 0.44% n-butane, is separated in the vessel 2 into the second top fraction 12 (1609 kmol/h) and the second bottom fraction 13 (34285 kmol/h). The stream 12 (45.58% nitrogen, 54.4% methane and 0.02% ethane) is heated to 33°C in the exchanger El to provide a stream 37 fed, at 4.9 bar, to the compressor Kl to the medium-pressure stage 14. The stream 13 (4.97% nitrogen, 87.30% methane, 5.20% ethane, 1.79% propane, 0.28% isobutane and 0.46% n-butane) is cooled in the heat exchanger E2 to provide the stream 20 at -157°C and 4.6 bar. This stream is expanded in the valve 28 to obtain the stream 29 at -165.21°C and 1.15 bar, which is introduced into the column CI. The column CI produces, at the top, the first top fraction 3 (4032 kmol/h) at -165.13°C. The fraction 3 (41.73% nitrogen and 58.27% methane) is heated in the iv^ exchanger El to give the stream 41 at -63.7°C and 1.05 bar. The stream 41 is fed into the low-pressure suction side 15 of the compressor Kl. The column CI produces the first bottom fraction 4 at -159.01°C and 1.15 bar with a flow rate of 30253 kmol/h. This fraction 4 (0.07% nitrogen, 91.17% methane, 5.90% ethane, 2.03% propane, 0.32% isobutane and 0.52% n-butane) is pumped by the pump PI to provide a fraction 39 at 4.15 bar and -158.86°C, then leaves the installation. The column CI is equipped with the column bottom reboiler 16 which cools the stream 13 to obtain the stream 20. The compressor Kl produces the compressed flow 5 at 37°C and 29 bar with a flow rate of 11341 kmol/h. This stream of fuel gas 5 (42.90% nitrogen and 57.09 methane) is split into a stream 40, which represents 3041 kmol/h, which leaves the installation, and a stream 6, which represents 8300 kmol/h, which is compressed in the compressor XKl. The compressor XKl products the compressed stream 7 at 68.18°C and 39.7 bar. The stream 7 is cooled to 37°C in the water exchanger 24, then split into the streams 8 and 9. The stream 8 (5700 kmol/h) is cooled in the exchanger El to yield the stream 25 at -74°C and 38.9 bar. The stream 9 (2600 kmol/h) is cooled in the exchanger El to yield the stream 22 at -155°C and 38.4 bar. The latter is then expanded in the valve 23 to provide the stream 35 at -168°C and 5.1 bar. The stream 25 is expanded in the expansion turbine XI which produces the fraction 10 at a temperature of Bf ^—5^— -139.7°C and a pressure of 8.0 bar. This fraction 10 is then heated in the exchanger El which produces the fraction 26 at a temperature of 32°C and a pressure of 7.8 bar. The fraction 26 is fed to the compressor Kl on the medium-pressure stage 11. The compressor Kl and the expander XI have the following performance: Denltrogenation unit Power of compressor Kl 22007 kW Power of expander XI 2700 kW The use of the vessel V2 allows a saving of about 2000 kW on the power of the compressor Kl. From these studies on the nitrogen-rich gas B, it is evident from the method according to the invention that: the increase in temperature of the LNG leaving the liquefication method makes it possible to obtain an increase in LNG production capacity of 1.2% per °C, the use of a denltrogenation column associated with liquefication of some of the fuel gas produced is far more effective than a final flash, saturation of the power of the gas turbine coupled to the compressor Kl by use of the novel method makes it possible to achieve a significant gain in LNG production capacity, the increase in the amount of fuel gas produced makes it possible to obtain an additional increase in the LNG production capacity, the addition of the separating vessel V2 makes it possible to improve the load on the compressor Kl and to lower the cost of its use. The following study relates to the use of the nitrogen-depleted gas A, in which the final flash unit produces no fuel gas. ^b - 35 - In a known way, natural gas containing very little nitrogen does not require the use of a final flash. The LNG can then be produced directly at -160°C and be sent for storage after expansion in a hydraulic turbine, for example similar to X3: this is the highly supercooled approach. When the highly supercooled technique is chosen the sources of fuel gas may be various: gas from the top of the methane remover, gas from the top of the condensate stabilization column, gas from the evaporation in the storage tanks, gas from regeneration of the natural gas dryers, etc. It is then no longer possible to add a source of fuel gas without running the risk of having excess fuel gas. If there is a desire to increase the capacity of the LNG production line by increasing the temperature of the LNG produced using the liquefication method, it is necessary to set up a method that produces little or no fuel gas. The method according to the invention makes it possible to achieve this objective. It makes it possible to increase the temperature of the LNG leaving the liquefication method and therefore to increase the flow rate of cooled LNG 4, produced for storage purposes. This method is set out in figure 6, and was described above. For the same power of turbine coupled to the compressor Kl, the operating conditions will depend on the capacity of the liquefication unit. The case of the use of LNG 1 from an LNG production unit comprising 2 GE7 turbines is described hereinafter by way of example: f ,-..36 - The LNG 1 at a temperature of -147 °C is expanded to 2.7 bar in the hydraulic turbine X3 driving an electric generator, then undergoes a second expansion to 1.15 bar in the valve 18, and is fed to the flash vessel VI, in a mixture with LNG from the liquefication of the compressed fuel gas 5. At the bottom of the vessel VI, the LNG is at -159.2 °C and 1.15 bar. It then leaves the installation and goes for storage. The fuel gas 3, which is the first top fraction, is heated to 32°C in the exchanger El before being compressed to 29 bar in the compressor Kl, to possibly feed into the fuel gas network. In this instance, all of the fuel gas is sent to the compressor XKl to provide the compressed stream 7 at 41.5 bar. This stream is then cooled to 37°C in the water exchanger 24, and is then split into two flows 8 and 9. The stream 8, which represents 79% of the stream 7, is cooled to -60°C before being fed to the turbine XI coupled to the compressor XKl. The turbine XI provides the expanded gas 10, at a pressure of 9 bar and a temperature of -127'C. This stream 10 is heated in the exchanger El to obtain a heated stream 26, at 32°C, then fed into the compressor Kl on the suction side of its third stage. The stream 9, which represents 21% of the stream 7, is liquefied and cooled to -141°C in the exchanger El and returns to the flash vessel VI. The use of the novel method has made it possible to increase by 15.82% the capacity of the liquefication sequence, for a reasonable on-cost. ir It must be understood that it is the combination of the recycling of the compressed fuel gas and of the expansion turbine cycle which leads to this highly surprising result. For LNG production units of different size, the results are given in: table 9, which corresponds to the characteristics of a unit operating according to the embodiment of the method of the invention as set out in figure 6, table 10, given by way of comparison, which sets out the characteristics of an LNG refrigeration unit using the highly supercooled approach. W Units 1 GET + 1 6E6 2 GE7 3 6E7 LN6 1 Temperature °C -144 -147 -151 Flow rate kg/h 430862 556506 799127 Cooled LN6 4 Flow rate kg/h 430862 556506 799127 Specific lower heat value kJ/kg 49334 49334 49334 Nitrogen content mol% 0.10 0.10 0.10 Production of LNG 4, lower heat value GJ/h % 21256 100 27455 115.82 39424 110.87 Fuel gas 5 Flow rate kg/h 0 0 0 Specific lower heat value kJ/kg 0 0 0 Production of fuel gas 5, specific lower heat value GJ/h 0 0 0 Final flash unit Power of compressor Kl kW 24000 24000 23543 Power of expander XI kW 4719 4719 4850 Performance Specific power of production of LNG 4 kJ/kg 1014 995 984 Ratio of power of Kl/production of LNG 4 0.0206 0.0202 0.0199 Additional production of LNG kg/h GJ/h 70489 3477 76010 3749 78381 3866 Table 9 4^ ■39 * Units 1 6E7 + 1 6E6 2 6E7 3 6E7 LN6 1 Temperature °C -160 -160 -160 Flow rate kg/h 360373 480496 720746 Cooled LN6 4 Flow rate kg/h 360373 480496 720746 Specific lower heat value kJ/kg 49334 49334 49334 Nitrogen content mol% 0.10 0.10 0.10 Production of LNG 4, lower heat value GJ/h O 17779 100.00 23705 100.00 35558 100.00 Fuel gas 5 Flow rate kg/h 0 0 0 Specific lower heat value kJ/kg 0 0 0 Production of fuel gas 5, specific lower heat value GJ/h 0 0 0 Final flash unit Power of compressor Kl kW 0 0 0 Power of expander XI kW 0 0 0 Performance Specific power of production of LNG 4 kJ/kg 973 973 973 Ratio of power of Kl/production of LNG 4 0.0197 0.0197 0.0197 Additional production of LNG kg/h GJ/h 0 0 0 0 0 0 Table 10 The increases in capacity for the use of an installation according to the method of the invention, by comparison with the highly supercooled approach, are as follows: 19.6% for an LNG unit using 1 GE6 turbine associated with one GE7 turbine, 15.8% for an LNG unit using 2 GE7 turbines, 10.9% for an LNG unit using 3 GE7 turbines. The embodiment of the method according to the invention according to figure 6 also allows the production of fuel gas, when this is desired. This eventuality is illustrated in a numerical example in table 11 below: Units 1 GE7 + 1 GE6 LNG 1 Temperature °c -143 Flow rate kg/h 583534 Cooled LN6 4 Flow rate kg/h 567402 Specific lower heat value kJ/kg 49351 Nitrogen content mol% 0.06 Production of LNG 4, lower heat value GJ/h % 28002 118.13 Fuel gas 5 Flow rate kg/h 16132 Specific lower heat value kJ/kg 48659 Production of fuel gas 5, specific lower heat value GJ/h 785 Final flash unit Power of compressor Kl kW 23888 Power of expander XI kW 3520 Performance Specific power of production of LNG 4 kJ/kg 976 Ratio of power of Kl/production of LNG 4 0.0198 Additional production of LNG kg/h GJ/h 86906 4297 Table 11 When the production of fuel gas rises from 0 to 785 GH/h, it is then possible to increase the capacity by 18.13%, that is to say that 2.31% of the increase in capacity (18.13% minus 15.82%) are due to the production of fuel gas. This result is far more pronounced than the one obtained with a denitrogenation installation. ka Another embodiment according to the method of the invention, employing a denitrogenation column CI, is set out in figure 7, described above. Unlike in figure 6, this embodiment uses a separating vessel V2. The LNG 1, of composition "A" obtained at -147°C at a pressure of 48.0 bar with a flow rate of 30885 kmol/h, is expanded to 2.7 bar and minus 147.63°C in the hydraulic turbine X3, then is expanded again to 2.5 bar and minus 148.33°C in the valve 18, to provide the expanded stream 2. The stream 2 (30885 kmol/h) is mixed with the stream 35 (3127 kmol/h) to obtain the stream 36 (34012 kmol/h) at -149.00°C. The stream 35 is made up of 3.17% nitrogen, 96.82% methane and 0.01% ethane. The stream 36, which is made up of 0.38% nitrogen, 91.90% methane, 4.09% ethane, 2.27% propane, 0.54% isobutane and 0.82% n-butane, is separated in the vessel V2 into the second top fraction 12 (562 kmol/h) and the second bottom fraction 13 (33450 kmol/h). The stream 12 (5.41% nitrogen, 94.57% methane and 0.02% ethane) is heated to 34 °C in the exchanger El, to provide a stream 37 which is fed, at 2.4 bar, to the compressor Kl to the medium-pressure stage 14. The stream 13 (0.03% nitrogen, 91.85% methane, 4.16% ethane, 2.31% propane, 0.55% isobutane and 0.83% n-butane) is expanded in the valve 28 to obtain the stream 29 at -159.17°C and 1.15 bar, which is introduced into the separating vessel VI. The vessel VI produces, at the top, the first top fraction 3 (2564 kmol/h) at -159.17°C. The fraction 3 (2.72% nitrogen, 97.27% methane and 0.01% ethane) is -—*5 heated in the exchanger El to give the stream 41 at minus 32.21°C and 1.05 bar. The stream 41 is fed into the low-pressure suction side 15 of the compressor Kl, The vessel VI produces the first bottom fraction 4 at -159.17°C and 1.15 bar with a flow rate of 30886 kmol/h. This fraction 4 (0,10% nitrogen, 91.40% methane, 4.50% ethane, 2.50% propane, 0.60% isobutane and 0.90% n-butane) is pumped by the pump PI to provide a fraction 39 at 4.15 bar and -159.02°C, then leaves the installation. The compressor Kl produces the compressed stream 5 at 37°C and 29 bar with a flow rate of 13426 kmol/h. This fuel gas stream 5 (3.18% nitrogen, 96.81% methane and 0.01% ethane) is compressed in full in the compressor XKl, without producing fuel gas 40. The compressor XKl produces the compressed stream 7 at 72.51°C and 42.7 bar. The stream 7 is cooled to 37°C in the water exchanger 24 and is then split into the streams 8 and 9. The stream 8 (10300 kmol/h) is cooled in the exchanger El to give the stream 25 at -56°C and 41.9 bar. The stream 9 (3126 kmol/h) is cooled in the exchanger El to give the stream 22 at -141°C and 41.4 bar. The latter stream is then expanded in the valve 23 to provide the stream 35 at -152.37°C and 2.50 bar. The stream 25 is expanded in the expansion turbine XI which produces the fraction 10 at a temperature of -129.65°C and a pressure of 8.0 bar. This fraction 10 is then heated in the exchanger El which produces the fraction 26 at a temperature of 34°C and a pressure of 7.8 bar. .-^ The fraction 26 is fed into the compressor Kl on the suction side of the medium-pressure stage 11. The compressor Kl and the expander XI have the following performance: Denitrogenation unit Kl Power of compressor Kl 23034 kW Power of expander XI 2700 kW The use of the vessel V2 allows a saving of about 1000 kW on the power of the compressor Kl. Finally, from these studies on gas A, which is nitrogen-depleted, it is evident from the method according to the invention that: the increase in the temperature of the LNG leaving the liquefication method makes it possible to obtain an increase in LNG production capacity of 1.2% per °C, this result being identical to the one obtained with gas A, the use of a final flash (vessel VI) and the saturation of the power of the gas turbine driving the compressor Kl makes it possible, by virtue of the method of the invention, to obtain a significant gain in LNG production capacity, without producing fuel gas, the production of fuel gas makes it possible to obtain an increase in the LNG production capacity. This gain is not insignificant and may prove to be a decisive factor, the addition of the separating vessel V2 makes it possible to improve the load on the compressor Kl and to reduce the cost of using it. ^f WE CLAIM : 1. A method for refrigerating a pressurized liquefied natural gas (1) containing methane and C2 and higher hydrocarbons, comprising a first step (I) in which step (la) said pressurized liquefied natural gas (1) is expanded to provide an expanded liquefied natural gas stream (2), in which step (lb) said expanded liquefied natural gas (2) is split into a relatively more volatile first top fraction (3) and a relatively less volatile first bottom fraction (4), in which step (Ic) the first bottom fraction(4) consisting of refrigerated liquefied natural gas is collected, in which step (Id) the first top fraction (3) is heated, compressed in a first compressor (Kl) and cooled to provide a first fiiel gas compressed fraction (5) which is collected, in which step (le) there is tapped off from the first compressed fraction (5) a second compressed fraction (6) which is then cooled, then mixed with the expanded liquefied natural gas stream (2), characterized in that the method comprises a second step (II) in which step (II) the second compressed fraction (6) is compressed in a second compressor (XKl) coupled to an expansion turbine (XI) to provide a third compressed fraction (7), in which step (lib) the third compressed fraction (7) is cooled, then split into a fourth compressed fraction (8) and a fifth compressed fraction (9), in which step (lie) the fourth compressed fraction (8) is cooled and expanded in the expansion turbine (XI) coupled to the second compressor (XKl) to provide an expanded fraction (10) which is then heated, then introduced into a medium pressure first stage (11) of the compressor (Kl), and in which step (lid) the fifth compressed fraction (9) is cooled, then mixed with the expanded liquefied natural gas stream (2) 2, The method as claimed in claim 1, wherein the expanded liquefied natural gas stream (2) is split, prior to step (lb), into a second top fraction (12) and a second bottom fraction (13), in that the second top fraction (12) is heated, then introduced into the first compressor (Kl) in an intermediate medium-pressure second stage(14) between the medium-pressure first stage (11) and a low-pressure stage (15), and in that the second bottom fraction (13) is split into the first top Suction (3) and the first bottom fraction (4). 46 3. The method as claimed in claim 1 or claim 2, wherein each compression step is followed by a cooling step. 4. The refrigerated liquefied natural gas (4) obtained by the method as claimed in any one of claims 1-3. 5. The fuel gas (5) obtained by the method as claimed in any one of claims 1-3. 6. An apparatus for refrigerating a pressurized liquefied natural gas, wherein the gas contains methane, C2 and higher hydrocarbons, the apparatus comprising: (la) first means for expanding the pressurized liquefied natural gas for providing an expanded liquefied natural gas stream; (lb) second means for splitting the expanded liquefied natural gas into a relatively more volatile first top fraction and a relatively less volatile first bottom fraction; (Ic) a first collector for collecting the first bottom fraction comprised of refrigerated liquefied natural gas; (Id) a heater for heating the first top fraction, a first compressor for compressing the heated top fraction and first cooling means for cooling the compressed top fraction for providing a ftiel gas compressed fraction, and a second collector for collecting the fiiel gas compressed fraction; (le) a tap for tapping off the fuel gas compressed fraction from the second collector for providing a second compressed fraction; second cooling means for cooling the second compressed fraction and a mixer for mixing the second compressed fraction with the expanded liquefied natural gas stream; (Ha) a second compressor for receivmg the second compressed fraction and for compressing the second compressed fraction, an expansion turbine coupled to the second compressor for providing a third compressed fraction from the compressor; 47 (nb) a first cooler for cooling the third compressed fraction; means for splitting the third compressed fraction into a fourth compressed fraction and a fifth compressed fraction; (lie) a second cooler for cooling the fourth compressed fraction and communicating the fourth compressed fraction to the expansion turbine coupled to the second compressor for providing an expanded fraction; a heater for heating the expanded fraction; the first compressor having a medium-pressure first stage into which the heated expanded fraction is communicated; (lid) a third cooler for cooling the fifth compressed fraction and a mixer for receiving the fifth compressed fraction and mixing the fifth compressed fraction with the expanded liquefied natural gas sfream. 7. The apparatus as claimed in claim 5, comprising: a means for splitting the expanded liquefied natural gas stream into a second top fraction and a second bottom fraction prior to (lb) the second means for splitting; means for heating and then for introducing the second top fraction into the first compressor in an intermediate medium-pressure second stage between the medium-pressure first stage and a low-pressure stage; and means for splitting the second bottom fraction into the first top fraction and the first bottom fraction. 8. The apparatus as claimed in claim 6, comprising a first separating vessel for separating the first top fraction and the first bottom fraction. 9. The apparatus as claimed in claim 6, comprising a distillation column for separating the first top fraction and the first bottom fraction. 48 10. The apparatus as claimed in claim 7, comprising a separating vessel for splitting the expanded liquefied natural gas stream into the second top fraction and the second bottom fraction. 11. The apparatus as claimed in claim 8, wherein the distillation column comprises at least one of a lateral or a column bottom reboiler; the distillation column having a plate and liquid is tapped off the plate of the distillation column and is connected to pass through the reboiler, a heat exchanger for heating the liquid passing through the reboiler, and a connection for reintroducing the heated liquid into the distillation column and a stage below the plate thereof; the expanded liquefied natural gas stream is communication with the heat exchanger to be cooled in the heat exchanger. 12. The apparatus as claimed in claim 10, wherein the heat exchanger s connected to the first, expanded, fourth and fifth compressed fractions for causing cooling of the first top fraction and of the expanded fraction and heating of the fourth and the fifth compressed fractions. 13. The apparatus as claimed in claim 11, wherein the heat exchanger communicates with a second top fraction for heating the second top fraction in the heat exchanger.

Full Text

The present invention relates, in general, and according to a first of its aspects, to the gas industry and, in particular, to a method for refrigerating pressurized gas containing methane and C2 and higher hydrocarbons, so as to separate then.
BACKGROUND OF INVENTION
US 3,616,652 (Dl) discloses in view of its figure, a process for refrigerating a liquefied natural gas 6 comprising a step in which the liquefied natural gas is expanded in a turbine 7, then a step in which the extended liquefied natural gas is splitted in a flask 11 into a relatively more volatile first top fraction 13 and into a relatively less volatile bottom fraction 12.
The bottom fraction 12 is collected. The first top fraction 13 is heated in exchangers 9,14,15,5, then compressed 16 before being cooled in refrigerant 17 to constitute a first compressed combustible gas fraction.
This fraction is compressed into a second compressor 18 to provide a third compressed fraction, the cooled into a refrigerant 19 before being split at separation 21 into a compressed fraction 23 and into a fifth compressed fraction 25,27.
The fourth compressed fraction 23 is cooled and expanded in turbine 22. A part of the fifth fraction is cooled and mixed at point 28 with the expanded liquefied natural gas flux.
More specifically, the invention relates according to its first aspect, to a method for refiigerating a pressurized liquefied gas containing methane and C2 and higher hydrocarbons comprising a first step (I) in which (la) said pressurized liquefied natural gas is expanded to provide an expanded liquefied natural gas stream, in which step (lb) said expanded liquefied natural gas is split in a relatively more volatile first top fraction and a relatively less volatile first bottom fraction, in which step (Ic) the first bottom fraction consisting of refrigerated liquefied natural gas is collected, in which step (Id) the first top fraction is heated, compressed in a first compressor and cooled to provide a first fiiel gas compressed fraction which is collected, in

which step (le) there is tapped off from the first compressed fraction a second compressed fraction which is then cooled, then mixed with the expanded liquefied natural gas stream.
Refrigeration method of this type are well known to those skilled in the art and have been in use for many years.
The method for refrigerating liquefied natural gas (LNG) according to the above
preamble is used in the known way with a view of eliminating the nitrogen present sometimes
in large quantities in the natural gas. In this case, the fuel gas obtained using this

method is nitrogen-rich, whereas the refrigerated liquefied natural gas is nitrogen-depleted.
Installations for liquefying natural gas have well-defined technical characteristics and limits dictated by the capacity of the production elements of which they are made. In consequence, an installation producing liquefied natural gas is limited by its maximum production capacity, under normal operating conditions. The only way to increase production consists in building a new production unit.
Given the cost that such an investment represents, it is necessary to make sure that the desired increase in production will be lasting, so as to make the cost easier to amortize.
At the present time there is no way to increase production of a liquefied natural gas production unit, even temporarily, when this unit is running at full capacity, without resorting to heavy and expensive investment consisting in building another production unit.
The liquefied natural gas (LNG) production capacity depends essentially on the power of the compressors used to refrigerate and liquefy the natural gas.
This being the case, a first object of the invention is to propose a method, in other respects in accordance with the generic definition given in the above preamble, that allows the capacity of an LNG production unit to be increased without having to resort to building another LNG production unit, and which is essentially characterized in that the method comprises a second step (II) in which step (Ila) the second compressed fraction is compressed in a second compressor coupled to an expansion turbine to provide a third compressed fraction, in which step (lib) the
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third compressed fraction is cooled, then split into a fourth compressed fraction and a fifth compressed fraction, in which step (lie) the fourth compressed fraction is cooled and expanded in the expansion turbine coupled to the second compressor to provide an expanded fraction which is then heated, then introduced into a medium-pressure first stage of the compressor, and in which step (lid) the fifth compressed fraction is cooled, then mixed with the expanded liquefied natural gas stream.
A first merit of the invention is that it has discovered that a production unit running at 100% capacity, producing a certain delivery of liquefied natural gas at a temperature of -IGCC and at a pressure close to 50 bar, all other operating parameters being constant, can have its delivery, and therefore its production, increased only by increasing the temperature at which the liquefied natural gas is produced.
However, the LNG is stored at about -160 °C at low pressure (under 1.1 bar absolute), and an increase in its storage temperature would lead to an increase in its storage pressure, and this represents prohibitive costs, and above all difficulties with transport, because of the very large quantities of LNG produced.
In consequence, it is common practice for the LNG to be prepared at a temperature close to -160°C prior to its being stored.
A second merit of the invention is that it presents an elegant solution to these limits on production by using a method for refrigerating LNG that can be adapted to an already-existing method for producing LNG, not requiring the use of significant financial and concrete means to implement this method. This solution comprises the production, by an already-existing LNG production
^

unit, of LNG at a temperature above about -160°C, then refrigerating it to about -160°C using the method according to the invention.
A third merit of the invention is that it has modified a known method in accordance with the preamble above for refrigerating nitrogen-rich liquefied natural gas and that it has allowed it to be used both with nitrogen-rich LNG and with nitrogen-depleted LNG. In the latter instance, the fuel gas obtained using this method contains very little nitrogen, and therefore has a composition close to that of the nitrogen-depleted liquefied natural gas.
According to a first aspect of the method of the invention, the expanded liquefied natural gas stream can be split, prior to step (lb), into a second top fraction and a second bottom fraction, the second top fraction can be heated, then introduced into the first compressor in an intermediate medium-pressure second stage between the medium-pressure first stage and a low-pressure stage, and the second bottom fraction can be split into the first top fraction and the first bottom fraction.
According to the first aspect of the method of the invention, each compression step can be followed by a cooling step.
According to a second of its aspects, the invention relates to a refrigerated liquefied natural gas and a fuel gas obtained by any one of the above-defined methods.
According to a third of its aspects, the invention relates to an installation for refrigerating a pressurized liquefied natural gas containing methane and C2 and higher hydrocarbons, comprising means for carrying out a first step (I) in which step (la) said
^

pressurized liquefied natural gas (1) is expanded to provide an expanded liquefied natural gas stream, in which step (lb) said expanded liquefied natural gas is split into a relatively more volatile first top fraction and a relatively less volatile first bottom fraction, in which step (Ic) the first bottom fraction consisting of refrigerated liquefied natural gas is collected, in which step (Id) the first top fraction is heated, compressed in a first compressor and cooled to provide a first fuel gas compressed fraction which is collected, in which step (le) there is tapped off from the first compressed fraction a second compressed fraction which is then cooled, then mixed with the expanded liquefied natural gas stream, characterized in that the installation comprises means for carrying out a second step (II) in which step (Ila) the second compressed fraction is compressed in a second compressor coupled to an expansion turbine to provide a third compressed fraction, in which step (lib) the third compressed fraction is cooled, then split into a fourth compressed fraction and a fifth compressed fraction, in which step (lie) the fourth compressed fraction is cooled and expanded in the expansion turbine coupled to the second compressor to provide an expanded fraction which is then heated, then introduced into a medium-pressure first stage of the compressor, and in which step (lid) the fifth compressed fraction is cooled, then mixed with the expanded liquefied natural gas stream.
According to a fii?^t alternative form according to its
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third aspect, the invention relates to an installation comprising means for splitting the expanded liquefied natural gas stream, prior to step (lb) , into a second top fraction and a second bottom fraction, in that the installation comprises means for heating, then introducing the second top fraction into the first compressor in an intermediate medium-pressure second stage between the medium-pressure first stage and a
^

low-pressure stage, and in that it comprises means for splitting the second bottom fraction into the first top fraction and the first bottom fraction.
According to a first embodiment according to its third aspect, the invention relates to an installation in which the first top fraction and the first bottom fraction are separated in a first separating vessel.
According to a second embodiment according to its third aspect, the invention relates to an installation in which the first top fraction and the first bottom fraction are separated in a distillation column.
According to one embodiment according to the first alternative form of its third aspect, the invention relates to an installation in which the expanded liquefied natural gas stream can be split into the second top fraction and the second bottom fraction in a second separating vessel.
According to its second embodiment according to its third aspect, the invention relates to an installation in which the distillation column comprises at least one lateral and/or column-bottom reboiler,, in that liquid tapped off a plate of the distillation column passing through said reboiler is heated in a second heat exchanger, then reintroduced into the distillation column at a stage below said plate, and in that the expanded liquefied natural gas stream is cooled in said second heat exchanger.
According to a third embodiment according to its third aspect, the invention relates to an installation in which the cooling of the first top fraction and of the expanded fraction, and the heating of the fourth compressed fraction and of the fifth compressed fraction take place in one and the same first heat exchanger.
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According to the first alternative form according to its third aspect, the invention relates to an installation in which the second top fraction is heated in the first heat exchanger.
The invention will be better understood and other objects, features, details and advantages thereof will become more clearly apparent in the course of the description which follows with reference to the attached schematic drawings given solely by way of nonlimiting example and in which:
figure 1 depicts a functional block diagram of an installation for liquefying natural gas according to one embodiment of the prior art;
figure 2 depicts a functional block diagram of an installation for removing nitrogen from liquefied natural gas according to a first embodiment of the prior art;
figure 3 depicts a functional block diagram of an
V
installation for removing nitrogen from liquefied natural gas according to a second embodiment of the prior art;
figures 4, 5, 6 and 7 depict functional block diagrams^ of installations possibly for removing nitrogen from liquefied natural gas according to some preferred embodiments of the invention.
stands for
stands for
stands for
stands for
stands for
In these seven figures, there are the symbols "FC", which stands for "flow controller", "GT" which stands for "gas turbine", "GE" which "electric generator", "LC" which "liquid level controller", "PC" which "pressure controller", "SC" which "speed controller" and "TC" which "temperature controller".
For clarity and succinctness, the pipes used in the installations of figures 1 to 7 will be identified by
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the same reference symbols as the gaseous fractions passing through them.
Referring to figure 1, the installation depicted is intended, in a known way, to treat a dried, desulfurized and decarbonated natural gas 100, to obtain liquefied natural gas 1, generally available at a temperature below -120°C.
This installation for liquefying LNG has two independent cooling circuits. A first cooling circuit 101, corresponding a propane cycle, makes it possible to obtain primary cooling to about -30°C in an exchanger E3 by expanding and vaporizing liquid propane. The heated and expanded propane vapor is then compressed in a second compressor K2, then the compressed gas 102 obtained is then cooled and liquefied in water coolers 103, 104 and 105.
A second cooling circuit 106, corresponding in general to a cycle operating on a mixture of nitrogen, methane, ethane and propane, allows significant cooling of the natural gas that is to be treated, to obtain liquefied natural gas 1. The heat transfer fluid present in the second cooling cycle is compressed in a third compressor K3 and cooled in water exchangers 118 and 119 and is then cooled in a water cooler 114 to obtain a fluid 107. The latter is then cooled and liquefied in the exchanger E3 to provide a cooled and liquefied stream 108. The latter is then split into a vapor phase 109 and a liquid phase 110 which are both introduced into the lower part of a cryogenic exchanger 111. After cooling, the liquid phase 110 then leaves the exchanger 111 to be expanded in a turbine X2 coupled to an electric generator. The expanded fluid 112 is then introduced into the cryogenic exchanger 111 above its lower part, where it is used to cool the fluids passing through the lower part of the exchanger, by being sprayed onto the pipes conveying the fluids that are to
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be cooled, using spray booms. The vapor phase 109 passes through the lower part of the cryogenic exchanger 111 where it is cooled and liquefied, and is then cooled further by passing through an upper part of the cryogenic exchanger 111. Finally, this cooled and liquefied fraction 109 is expanded in a valve 115, then used to cool the fluids passing through the upper part of the cryogenic exchanger 111, by spraying it onto the pipes conveying the fluids that are to be cooled. The liquid coolants sprayed inside the cryogenic exchanger 111 are then collected at the bottom of the exchanger to provide the stream 106 which is sent to the compressor K3.
The dried, desulfurized and decarbonated natural gas 100 is cooled in a propane heat exchanger 113 and then subjected to a drying treatment, which may, for example, involve passing it over a molecular sieve, for example made of zeolite, and to a demercurization treatment, for example by passing it over a silver foam or over any other mercury trap, in a chamber 116 to provide a purified natural gas 117. The latter is then cooled and partially liquefied in the heat exchanger E3, passes through the lower part, then through the upper part of the cryogenic exchanger 111 to provide a liquefied natural gas 1. The latter is customarily obtained at a temperature below -120°C.
Referring now to figure 2, the installation depicted is intended, in the known way, to treat a nitrogen-rich liquefied natural gas 1 to obtain, on the one hand, a nitrogen-depleted cooled liquefied natural gas 4 and, on the other hand, a first compressed fraction 5 which is a nitrogen-rich compressed fuel gas.
The LNG 1 is first of all expanded and cooled in an expansion turbine X3 which is regulated by a flow controller controlling the flow of LNG passing through the pipe 1, then is expanded and cooled again in a
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valve 18 the opening of which is dependent on the pressure of the LNG leaving the compressor X3, to provide an expanded liquefied natural gas stream 2. The latter is then split into a relatively more volatile first top fraction 3 and a relatively less volatile bottom fraction 4 in a vessel VI. The first bottom fraction 4 consisting of cooled liquefied natural gas is collected and pumped in a pump PI, passes through a valve 19, the opening of which is regulated by a level controller controlling the level of liquid in the bottom of the vessel VI, to then leave the installation and go for storage.
The first top fraction 3 is heated in a first heat exchanger El and is then introduced into a low-pressure stage 15 of a compressor Kl coupled to a gas turbine GT. This compressor Kl comprises a plurality of compression stages 15, 14, 11 and 30, at progressively higher pressures, and a plurality of water coolers 31, 32, 33 and 34. After each compression stage, the compressed gases are cooled by passing them through a heat exchanger, preferably a water heat exchanger. The first top fraction 3, at the end of the compression and cooling steps, provides the nitrogen-rich compressed fuel gas 5. This fuel gas is then collected and leaves the installation.
A small part of the fuel gas 5 which corresponds to a stream 6 is tapped off. This stream 6 is cooled in the exchanger El, giving up its heat to the first top fraction 3, to yield a cooled stream 22. This cooled stream 22 then flows through a valve 23 the opening of which is controlled by a flow controller at the outlet of the exchanger E2. The stream 22 is finally mixed with the expanded liquefied natural gas stream 2.
Referring now to figure 3, the installation depicted is intended, in the known way, to treat a nitrogen-rich liquefied natural gas 1 to obtain, on the one hand, a
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installation, the separating vessel VI has been replaced by a distillation column Cl and a heat exchanger E2.
The LNG 1 is first of all expanded and cooled in an expansion turbine X3 the speed of which is controlled by a flow controller controlling the flow of LNG through the pipe 1, and is then cooled in the heat exchanger E2 to provide a cooled stream 20. The latter passes through a valve 21, the opening of which is controlled by a pressure controller on the pipe 20, upstream of said valve 21, to provide an expanded liquefied natural gas stream 2. The expanded liquefied natural gas stream 2 is then split into a relatively more volatile first top fraction 3 and a relatively less volatile first bottom fraction 4 in the column Cl. The first bottom fraction 4 consisting of cooled liquefied natural gas is collected and pumped in a p^imp PI, passes through a valve 19 the opening of which is controlled by a level controller controlling the level of liquid in the bottom of the vessel VI, and then leaves the installation and goes for storage.
The column Cl comprises a column bottom reboiler 16 which uses liquid contained on a plate 17. The stream passing through the reboiler 16 is heated in the heat exchanger E2 and then introduced into the bottom of the column Cl.
The first top fraction 3 follows the same treatment as set out in figure 2, to obtain a first compressed gas fraction 5, which is a nitrogen-rich compressed fuel gas, and a second compressed fraction 6 which is a tapped-off compressed fuel gas fraction. Similarly, the latter fraction is heated in the exchanger El to yield a cooled stream 22. This stream 22 is also mixed with the expanded liquefied natural gas stream 2.
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a cooled stream 22. This stream 22 is also mixed with the expanded liquefied natural gas stream 2.
Referring now to figure 4, the installation depicted is intended, with the aid of a device according to the method of the invention, to treat a nitrogen-rich liquefied natural gas 1 to obtain, on the one hand, a nitrogen-depleted and cooled liquefied natural gas 4 and, on the other hand, a nitrogen-rich compressed fuel gas 5.
This installation comprises elements in common with figure 3, particularly the expansion and cooling of the LNG 1 to obtain the expanded LNG stream 2. Likewise, the splitting into the first top fraction 3 and the first bottom fraction 4 is performed in a similar way in the column CI. Finally, the fuel gas stream 5 is obtained, as before, by successive compression and cooling operations. Unlike the method set out in figure 3, a second compressed fraction 6, tapped off the first compressed gas fraction 5 is fed to a compressor XKl coupled to an expansion turbine XI to obtain a third compressed fraction 7. This fraction is cooled in a water cooler 24, then split into a fourth compressed fraction 8 and a fifth compressed fraction 9.
The fourth compressed fraction 8 is cooled in the heat exchanger" El to provide a fraction 25 which is expanded in the turbine XI. The turbine XI supplies an expanded stream 10 which is heated in the exchanger El to give a heated expanded stream 26. This heated expanded stream 26 is introduced into a medium-pressure stage 11 of the compressor Kl.
The fifth compressed fraction 9 is cooled in the heat exchanger El to provide a fraction 22 which is expanded in a valve 23 then mixed with the expanded LNG fraction 2.
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The expander XI comprises an inlet guide valve 27 making it possible, by varying the angle at which the stream 25 is introduced to the blades of the turbine XI, to vary the speed at which the latter rotates, and therefore to cause the power delivered to the compressor XKl to vary.
Referring now to figure 5, the installation depicted is intended, with the aid of a device according to the method of the invention, to treat a liquefied natural gas 1, preferably nitrogen rich, to obtain, on the one hand, a cooled and nitrogen-depleted liquefied natural gas 4 and, on the other hand, a nitrogen-rich compressed fuel gas 5, when the liquefied natural gas 1 contains nitrogen.
This installation comprises elements in common with figure 4, particularly the production, by a distillation column CI, of a first top fraction 3 and of a first bottom fraction 4. Similarly, the first top fraction 3 is compressed in a compressor Kl and cooled in coolers 31 - 34 to obtain a first compressed fraction 5. A second tapped-off fraction 6 is tapped off the first compressed fraction 5 to be compressed in a compressor XKl coupled to an expansion turbine XI, which at outlet produces a third compressed fraction 7. The latter is split into a fourth compressed fraction 8 and a fifth compressed fraction 9.
The fourth compressed fraction 8 is cooled in the heat exchanger El to provide a fraction 25 which is expanded in the turbine XI. The turbine XI supplies an expanded stream 10 which is heated in the exchanger El to give a heated expanded stream 26. This heated expanded stream 26 is introduced into a medium-pressure stage 11 of the compressor Kl.
The fifth compressed fraction 9 is cooled in the heat exchanger El to provide a fraction 22 which is expanded
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in a valve 23, then mixed with the expanded LNG fraction 2.
The expander XI comprises an inlet guide valve 27 whose purpose was defined in the description of figure 4.
Unlike figure 4, the installation depicted in figure 5 further comprises a separating vessel V2 in which the expanded natural gas stream 2 is split into a second top fraction 12 and a second bottom fraction 13.
The second top fraction 12 is heated in the exchanger El then introduced into a medium-pressure stage 14 of the compressor Kl, at a pressure that it is intermediate between the inlet pressure of the low pressure stage 15 and that of the medium-pressure stage 11.
The second bottom fraction 13 is cooled in an exchanger E2 to produce a cooled LNG fraction 20. This last fraction is expanded and cooled in a valve 28 to produce an expanded and cooled LNG fraction 29. The opening of the valve 28 is controlled by a level controller controlling the level of liquid contained in the vessel V2. The stream 29 is then introduced into the column CI where it is split into the first top fraction 3 and the first bottom fraction 4.
As indicated during the description of figure 4, the column CI comprises a reboiler 16 which taps off liquid contained on a plate 17 of the column CI to heat it in the exchanger E2 by heat exchange with the stream 13, and introduce it into the bottom of the column. Likewise, the first bottom fraction 4 is pumped by a pump PI and passes through a valve 19 the opening of which is controlled by a level controller controlling the level of liquid present in the bottom of the column CI.

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Referring now to figure 6, the installation depicted is intended, with the aid of a device according to the method of the invention, to treat a liquefied natural gas 1, preferably nitrogen-depleted, to obtain, on the one hand, a cooled and nitrogen-depleted liquefied natural gas 4 and, on the other hand, a nitrogen-rich compressed fuel gas 5, when an LNG 1 rich in nitrogen is used.
This installation comprises elements common to figure 2 and figures 4 and 5.
In a simplified way, figure 6 is structurally similar to figure 4 except that the column CI has been replaced by a separating vessel VI, and the exchanger E2 has been omitted, because there is no reboiler when using a separating vessel. The expanded LNG stream 2 is therefore introduced directly into the separating vessel VI to be split into a first top fraction 3 and a first bottom fraction 4.
Replacing the column CI with the vessel VI does not alter the sequence of steps of the method as described for figure 5. By contrast, because the vessel VI does not have such good separation performance as the column CI, the cooled LNG 4 will normally contain more nitrogen when a device according to figure 6 is used than when a device according to figure 5 is used. Of course, the LNG 1 used in both instances is physically and chemically identical, and contains at least a little nitrogen.
Referring to figure 7, the installation depicted is intended, with the aid of a device according to the method of the invention, to treat a liquefied natural gas 1, preferably nitrogen-depleted, to obtain, on the one hand, a cooled liquefied natural gas 4 and, on the other hand, a compressed fuel gas 5.
M-

This installation comprises elements common to figure 2 and to figures 4, 5 and 6.
In a simplified way, figure 7 is structurally similar to figure 5 except that the column CI has been replaced by a separating vessel VI, and the exchanger E2 has been omitted, because there is no reboiler when using a separating vessel. The expanded LNG stream 2 is therefore introduced directly into the separating vessel V2 to be split into a second top fraction 12 and a second bottom fraction 13.
The second top fraction 12 is heated in an exchanger El then introduced into a compressor Kl at an intermediate medium-pressure stage 14, between a low-pressure stage 15 and a medium-pressure stage 11, in the same way as described for figure 5.
Replacing the column CI with the vessel VI does not alter the sequence of steps of the method as described for figure 5. By contrast, because the vessel VI does not have such good separating performance as the column CI, the cooled LNG 4 will normally contain more nitrogen when a device according to figure 6 is used than when a device according to figure 5 is used. Of course, in order to allow for a valid comparison, the LNG 1 used in both cases is physically and chemically identical.
In order to allow a material assessment of the performance of an installation operating according to a method according to the invention, numerical examples are now given, for illustrative rather than limitative purposes.
These examples are given on the basis of two different natural gases "A" and "B", the composition of which is given below in table 1:
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Component Natural L gas A Natural Gas B

Molar
composition
(%) Composition by mass (%) Molar
composition
(%) Composition by mass (%)
Nitrogen 0.100 0.155 3.960 6.127
Methane Ethane 4.500 ,7.510 5.360 8.902
Propane 2.500 6.118 1.845 4.493
i-Butane 0.600 1.935 0.290 0.931
n-Butane 0.900 2.903 0.470 1.509
Total 100.000 100.000 100.000 100.000
Table 1
These gases are deliberately free of C5 and higher hydrocarbons, so as not to make the calculations any more complicated.
The other operating conditions are identical and as follows (the reference numerals relate to fig. 1): temperature of the wet natural gas 100: 37°C pressure of the wet natural gas 100: 54 bar pre-cooling by the cooler 113 prior to drying: 23°C
temperature of the dry gas after it has passed through chamber 116: 23.5°C pressure of the dry gas: 51 bar temperature of the cooling water: 30°C temperature at the exit of CTie water exchanger: 37°C
temperature at which propane condenses: 47°C efficiency of the centrifugal compressors Kl, K2 and K3: 82%
efficiency of the expansion turbine X2: 85% efficiency of the axial compressor XKl: 86% power on a GE6 shaft run: 31570 kW power on a GE7 shaft run: 63140 kW power on a GE5D shaft run: 24000 kW
/f

The power on a shaft run represents the power available on a shaft of a general electric gas turbine reference GE5D, GE6 and GE7. Turbines of this type are coupled to the compressors Kl, K2 and K3 depicted in figures 1-7.
The deliveries of natural gas to be liquefied will be chosen to saturate the available power on the shaft runs. The following three cases are envisioned (for a liquefication method described in figure 1):
Use for driving one GE6 turbine and one GE7 turbine, which "corresponds to a delivery of LNG produced at -160°C of about 3 million tonnes per year.
Use for driving two GE7 turbines, which correspondsto a delivery of LNG produced at -160°C of about 4 million tonnes per year.
Use for driving three GE7 turbines, which corrBsponds to a delivery of LNG produced at -160°C of about 6 million tonnes per year.
One of the ways for easily calculating the influence of
a parameter without going into the details of a method
is that of the idea of Theoretical Work associated with
the idea of Exergy.
The theoretical work that has to be given to a system in order to cause it to change from state 1 to state 2 is given by the following equation:
Wl-2 = TO X (SI - S2) - (HI - H2)
With:
TO SI S2 HI H2
Wl-2: theoretical work (kJ/kg)
temperature at which heat is rejected (K) entropy in state 1 (kJ/(K.kg)) entropy in state 2 (kJ/(K.kg)) enthalpy in state 1 (kJ/kg) enthalpy in state 2 (kJ/kg)
M

—±s—
In this instance, the rejection temperature will be taken as being equal to 310.15 K (37°C). State 1 will be the natural gas at 37°C and 51 bar and state 2 will be the LNG at a temperature T2 and at 50 bar.
Table 2 below shows the change in theoretical work to liquefy natural gases A and B according to the temperature of the LNG leaving the liquefication method. When the power of the refrigeration compressors is constant, the reduction in theoretical work results in a possible increase in the capacity of the liquefication cycle.

Temperature
of the LNG 1
(°C) Natural Gas A

Theoretical
work
(kJ/kg) Theoretical
work
(%) Possible
capacity
(%)
-130 356.63 71.19 140.46
-135 376.93 75.25 132.90
-140 398.45 79.54 125.72
-145 421.57 84.16 118.82
-150 446.24 89.08 112.26
-155 472.64 94.35 105.99
-160 500.93 100.00 100.00
'k'kifirififie'kic'k'k'^ Natural Gas B
-130 355.89 71.35 140.16
-135 376.04 75.39 132.65
-140 397.43 79.67 125.51
-145 420.23 84.24 118.70
-150 444.56 89.12 112.21
-155 470.74 94.37 105.97
-160 498.82 100.00 100.00
Table 2
It can be seen that the figures obtained with the gases A and B are very similar. The possible increase in capacity is about 1.14% per °C of temperature of the LNG 1 obtained at the exit of the liquef ication unit set out in figure 1.
The capacity Cl for a temperature Tl of the LNG produced can be expressed as a function of the capacity CO at the temperature TO, using the following equation:
i/

CI = CO X 1.0114

(Tl - TO)

With:
CI
CO
Tl
T2
capacity to produce LNG at Tl (kg/h) capacity to produce reference LNG at TO (kg/h) LNG production temperature (°C) reference LNG production temperature (°C)

As a result, at -140°C, the capacity of the LNG production unit is 125.5% of its capacity at -160°C, which is a considerable difference.
The actual work of an LNG production unit will obviously be dependent upon the method chosen. The method depicted in figure 1, which is known by the name of MCR®, is a well known method widely used and developed by the company APCI.
This method is used here in a special way that gives it very good performance: the propane cycle has 4 stages and the MCR (multiple component refrigerant, stream 106, fig. 1) refrigeration and propane refrigeration (stream 102, fig. 1) takes place in the heat exchanger E3, which is a brazed aluminum plate-type exchanger.
The results obtained are set out table 3:
(PCS^

Temperature
of the LNG 1
(°C) Natural Gas A

Actual work (kJ/kg) Actual work (%) Possible
capacity
(%)
-130 702.77 72.23 138.45
-135 739.93 76.05 131.50
-140 781.25 , 80.29 124.54
-145 820.56 84.33 118.58
-150 867.88 89.20 112.11
-155 917.44 94.29 106.05
-160 972.99 100.00 100.00
***•*•*•*■*••*•■*•** Natural Gas B
-130 688.86 71.24 140.37
-135 728.22 75.31 132.78
-140 772.16 79.86 125.23
-145 814.34 84.22 118.74
-150 861.75 89.12 •1. A. £^ m £m J.
-155 94.37 105.97
-160 100.00 100.00
Table 3
It can be seen that these results per^fectly corroborate those obtained using the theoretical work calculations and set out in table 1.
The efficiency of the liquefication method can be calculated from the actual work and from the theoretical work. The latter is roughly constant and is round about 51.5%, as can be seen from the results given in table 4:

Temperature
of the LNG 1
(°C) Natural Gas A

Theoretical
work
(kJ/kg) Actual work (%) Efficiency (%)
-130 356.63 702.77 50.75
-135 376.93 739.93 50.94
-140 398.45 781.25 51.00
-145 421.57 820.56 51.38
-150 446.24 867.88 51.42
-155 472.64 917.44 51.52
-160 500.93 972.99 51.48
***■*■■*■■*■*■*•**** Natural Gas B
-130 355.89 688.86 51.66
-135 376.04 728.22 51.64
-140 397.43 772.16 51.47
-145 420.23 814.34 51.60
-150 444.56 861.75 51.59
Table 4
This result is particularly satisfying. The user of the method will always be assured of making best use of the liquefication method, regardless of the chosen temperature at which the LNG is produced. It can also be seen that the composition of the natural gas that is to be liquefied has no importance.
Thus, the novel use of the known liquefication method makes it possible to increase the temperature of the LNG 1 obtained at the outlet of the production unit while at the same time allowing a substantial increase in the quantity produced, which may range as high as about 40% at -130°C.
The LNG 1 obtained at the outlet of the production unit described above for figure 1, can have its nitrogen removed in a denitrogenation unit such as depicted in figure 2 or in figure 3. This nitrogen-removal operation is needed when the natural gas extracted from the source contains nitrogen in relatively high proportions, for example upwards of 0.100 mol% to about 5 to 10 mol%.
M

produce LNG 1, and "3 GE7" corresponds to the use of 3 turbines:

Units 1 GE7
+ 1 GE6 2 6E7 3 6E7
LNG 1
Temperature °C -150 -150 -150
Flow rate kg/h 406665 542219 813330
Cooled LNG 4
Flow rate kg/h 368990 491985 737980
Specific lower heat value kJ/kg 48412 48412 48412
Nitrogen content mol% 1.38 1.38 1.38
Production of LNG 4, lower heat value GJ/h % 17864 100 23818 100 35727 100
Fuel gas 5
Flow rate kg/h 37676 50235 75352
Specific lower heat value kJ/kg 27492 27492 27492
Production of fuel gas 5, specific lower heat value GJ/h 1036 1381 2072
Denitrogenation unit
Power of compressor
Kl kW 7037 9383 14074
Performance
Specific power of production of LNG kJ/kg 1019 1019 1019
Ratio of power of Kl/production of LNG 4 0.0210 0.0210 0.0210
Table 5
The installation depicted schematically in figure 3 is an LNG denitrogenation unit with a denitrogenation column. Replacing the flash in the vessel VI with a denitrogenation column CI allows an appreciable improvement in the efficiency with which the nitrogen contained in the LNG 1 is extracted.
In this installation, the LNG 1 at -145.5°C is expanded to 5 bar in the expansion hydraulic turbine X3, then is cooled from -146.2°C to -157'C in the exchanger E2 by exchange of heat with the liquid flowing through the
^

column bottom reboiler 16 to obtain an expanded and cooled LNG stream 20. The stream 20 undergoes a second expansion to 1.15 bar in a valve 21 and feeds into the denitrogenation column CI as a mixture with the LNG 22 from the partial recycling of the compressed fuel gas 5.
At the bottom of the denitrogenation column CI, the LNG contains 0.06% nitrogen, whereas the nitrogen content of the LNG using a final flash was 1.38% (fig. 2 and table 5). This column bottom LNG is pumped by a pump PI and represents a cooled LNG fraction 4 which is sent for storage.
The fuel gas 3, which is the first top fraction from the column CI, is heated to -75°C in the exchanger El, then compressed to 29 bar in the compressor Kl and cooled by the water coolers 31 - 34 to provide a compressed fuel gas 5.
A stream 6, which represents 23% of the compressed gas 5 is recycled to the column CI after the heating of the stream 3 in the exchanger El.
The fuel gas produced, which represents 1032 GJ/h in the case of the use of one GE6 turbine and one GE7 turbine, is roughly identical in terms of total calorific value to that of the final flash unit of fig. 2. The same is true when using more substantial LNG production units (2 or 3 GE7s).
The use of the technique of removing nitrogen in a denitrogenation column has made it possible to increase by 5.62% the capacity of the liquefication process, for a minor on-cost.
It must be understood that it is the combination of use of a denitrogenation column CI and of the recycling of fuel gas which leads to this highly encouraging result.
U.f

^ 26 -
The power of the fuel gas compressor Kl depends on the size of the unit. It will be:
8087 kW for an LNG unit using 1 GE6 combined with
1 GE / r
10783 kW for an LNG unit using 2 GE7s, 16174 kW an LNG unit using 3 GE7s.
The powers of these machines and the start-up problems mean that it is desirable to use a gas turbine to drive the fuel gas compressor Kl. The other performance data for the method are given in table 6:

Units 1 GE7
+ 1 GE6 2 GE7 3 GE7
LNG 1
Temperature "C -145.5 -145.5 -145.5
Flow rate kg/h 428175 570899 856350
Cooled LNG 4
Flow rate kg/h 381659 508877 763318
Specific lower heat value kJ/kg 49434 49434 49434
Nitrogen content mol% 0.06 0.06 0.06
Production of LNG 4, lower heat value GJ/h % 18867 105.62 25156 105.62 37734 105.62
Fuel gas 5
Flow rate kg/h 46517 62023 93034
Specific lower heat value kJ/kg 22191 22191 22191
Production of fuel gas 5, specific lower heat value GJ/h 1032 1376 2065
Denitrogenation unit
Power of compressor Kl kW 8087 10783 16174
Performance
Specific power of production of LNG kJ/kg 995 995 995
Ratio of power of Kl/production of LNG 4 0.0201 0.0201 0.0201
Additional production of LNG kg/h GJ/h 12669 1003 16892 1338 25338 2007
Table 6
One of the main problems encountered in industrial installations for treating and liquefying gases is
^

- 27 ■ ■
related in particular to the optimum use of the compression apparatus which represents a significant investment, both in terms of initial purchase and in terms of power consumption. Indeed, compressors requiring power of the order of several tens of thousand kW need to be reliable and to be able to be used under conditions of optimum efficiency over the broadest possible range of loads. Of course, this comment also applies to the means used to run them, these means here usually being gas turbines, because of the commercially available range of powers.
Gas turbines in order to be efficient, need to be used at full capacity. Consider the example of a denitrogenation unit operating according to any one of the embodiments described in figures 2 and 3. The gas turbine driving the compressor Kl needs to have a maximum power tailored to the power required by the compressor, so as to obtain the most favorable possible compression efficiency.
However, a gas turbine may find itself operating under conditions such that the power delivered to the compressor is markedly below its capacity.
This is the case for example when a GE5d gas turbine, with a power of 24000 kw, is coupled to the compressor Kl when nitrogen is being removed by final flash or by separation in a column. The consequence of this underuse of the turbine is a reduction in the energy efficiency of the compression stage relative to the power consumption of the turbine.
Of course, the power of the compressor Kl varies according to the size of the unit, as was explained above. Thus, the use of a GE5d turbine makes it possible to enjoy excess power amounting to:
15913 kW for an LNG unit using 1 GE6 turbine associated with 1 GE7 turbine.
Jil

> 28 -
13217 kW for an LNG unit using 2 GET turbines, 7826 kW for an LNG unit using 3 GE7 turbines.
It is therefore desirable to use this excess available power. The method according to the invention in particular proposes to use all of the available power to drive the compressor Kl.
The method according to the invention also makes it possible to increase the temperature at the outlet of the liquefication method, to obtain the LNG stream 1, and to use the excess power available on the gas turbine driving Kl to cool the LNG to -160°C.
Furthermore, the method according to the invention makes it possible,^ because of the possibility of increasing the temperature of the LNG 1 produced for example according to the APCI method, to increase the flow rate of LNG cooled to -160°C substantially, to an extent which in some cases may be by about 40%.
The method of the invention has the merit that it can be implemented easily, because of the simplicity of the means needed to embody it.
One embodiment according to the method of the invention, employing a denitrogenation column CI, is set out in figure 4, described above. For the same turbine power driving the compressor Kl, the operating conditions will depend on the capacity of the natural gas liquefication unit.
An LNG 1 is produced at -140.5°C using the APCI method dgpTcted in figure 1. This method is implemented using two GE7 gas turbines to drive the compressors K2 and K3. The LNG 1 enters the installation set out in figure 4. It is expanded to 6.1 bar in the expansion hydraulic turbine X3 driving an electric generator, then cooled from -141.2 to -157 "C in a heat exchanger
s&

E2 by exchange of heat with a liquid passing through a column bottom reboiler 16 to provide a cooled LNG 21. The latter is expanded to 1.15 bar in a valve 21 to obtain an expanded stream 2 which is fed into a column CI as a mixture with a stream 22, as indicated above in the description of the figures.
The LNG stream 4, tapped off at the bottom of the column CI, contains 0.00% nitrogen.
The fuel gas 3 is heated to -34 "C in the exchanger El, then is compressed to 29 bar in the compressor Kl to feed into a fuel gas network.
A first difference compared with the known method stems from the amount of compressed gas 6 tapped off the fuel gas stream 5: this is now up to about 73%. This compressed gas 6 is compressed to 38.2 bar in the compressor XKl to provide a fraction 7. The latter is cooled to 37°C in a water exchanger 24 then split into two flows 8 and 9.
The flow 8, which is the larger flow, representing 70% of the stream 7, is cooled to -82°C by passing through the exchanger El, then is fed to the turbine XI, coupled to the compressor XKl. The expanded stream leaving the turbine 10, at a pressure of 9 bar and a temperature of -138°C, is heated in the exchanger El to 32 °C then fed into the compressor Kl at a medium-pressure stage 11 which is the third stage.
The flow 9, which is the smaller flow, representing 30% of the stream 7, is liquefied and cooled to -160°C and returns to the denitrogenation column 01.
The fuel gas produced represents 1400 GJ/h, and is identical in total calorific value to that of the final flash unit. The use of the denitrogenation technique and of the method of the invention has made it possible
M^

to increase by 11.74% the capacity of the liquefication sequence, for a reasonable on-cost.
It must be understood that it is the combination of the use of a denitrogenation column, of the recycling of the compressed fuel gas and of the expansion turbine cycle which leads to this highly surprising result.
For the other sizes of LNG production unit, the results are given in table 7:

Units 1 6E7
+ 1 6E6 2 GE7 3 GE7
LNG 1
Temperature 'C -138.5 -140.5 -143.5
Flow rate kg/h 462359 602827 875470
Cooled LNG 4
Flow rate kg/h 413619 537874 781438
Specific lower heat value kj/kg 49479 49479 49479
Nitrogen content mol% 0.00 0.00 0.00
Production of LNG 4, lower heat value GJ/h % 20465 114.57 26613 111.74 38661 108.21
Fuel gas 5
Flow rate kg/h 48713 64994 94055
Specific lower heat value kJ/kg 21008 21535 21521
Production of fuel gas 5, specific lower heat value GJ/h 1023 1400 2024
Denitrogenation unit
Power of compressor Kl kW 23963 23970 23990
Power of expander XI kW 2835 2058 1175
Performance
Specific power of production of LNG kJ/kg 1056 1030 983
Ratio of power of Kl/production of LNG 4 0.0213 0.0208 0.0199
Additional production of LNG kg/h GJ/h 44629 2602 45889 2795 43458 2934
Table 7
It can be seen that the increases in capacity are by: - 14.2% for an LNG unit using one GE7 turbine associated with one GE6 turbine,
11.7% for an LNG unit using two GE7 turbines.
M

8.21% for an LNG unit using three GE7 turbines.
The method according to the invention also has a considerable benefit in regulating the amount of fuel gas produced. Indeed, it is now possible to have sustained production of fuel gas, as shown in a numerical example in table 8 below:

Units 2 GE7
LNG 1
Temperature °c -135
Flow rate kg/h 641176
Cooled LNG 4
Flow rate kg/h 546088
Specific lower heat value kJ/kg 49454
Nitrogen content mol% 0.00
Production of LNG 4, lower heat value GJ/h % 27006 113.39
Fuel gas 5
Flow rate kg/h 95092
Specific lower heat value kJ/kg 29361
Production of fuel gas 5, specific lower heat value GJ/h 2792
Denitrogenation unit
Power of compressor Kl kW 23900
Power of expander XI kW 802
Performance
Specific power of production of LNG 4 kJ/kg 1014
Ratio of power of Kl/production of LNG 4 0.0205
Additional production of LNG kg/h GJ/h 54103 3188
Table 8
It can be seen that when the amount of fuel gas rises from 1400 to 2800 GJ/h, it is then possible to increase the capacity by 13.39%, that is to say that 1.65% increase in capacity (13.39% minus 11.74%) are due to the increase in production of fuel gas.
Another embodiment according to the method of the invention, employing a denitrogenation column 01, is set out in figure 5 described above. Unlike in

figure 4, this embodiment employs a separating vessel V2.
The LNG 1, of composition "B" obtained at -140.5°C under a pressure of 48.0 bar with a flow rate of 33294 kmol/h, is expanded to 6.1 bar and minus 141.25°C in the hydraulic turbine X3, then expanded again to 5.1 bar and -143.39°C in the valve IB, to provide the expanded stream 2.
The stream 2 (33294 kmol/h) is mixed with the stream 35 (2600 kmol/h) to obtain the stream 36 (35894 kmol/h) at -146.55°C.
The stream 35 is made up of 42.97% nitrogen, 57.02% methane and 0.01% ethane.
The stream 36, which is made up of 6.79% nitrogen, 85.83% methane, 4.97% ethane, 1.71% propane, 0.27% isobutane and 0.44% n-butane, is separated in the vessel 2 into the second top fraction 12 (1609 kmol/h) and the second bottom fraction 13 (34285 kmol/h).
The stream 12 (45.58% nitrogen, 54.4% methane and 0.02% ethane) is heated to 33°C in the exchanger El to provide a stream 37 fed, at 4.9 bar, to the compressor Kl to the medium-pressure stage 14.
The stream 13 (4.97% nitrogen, 87.30% methane, 5.20% ethane, 1.79% propane, 0.28% isobutane and 0.46% n-butane) is cooled in the heat exchanger E2 to provide the stream 20 at -157°C and 4.6 bar. This stream is expanded in the valve 28 to obtain the stream 29 at -165.21°C and 1.15 bar, which is introduced into the column CI.
The column CI produces, at the top, the first top fraction 3 (4032 kmol/h) at -165.13°C. The fraction 3 (41.73% nitrogen and 58.27% methane) is heated in the
iv^

exchanger El to give the stream 41 at -63.7°C and 1.05 bar. The stream 41 is fed into the low-pressure suction side 15 of the compressor Kl.
The column CI produces the first bottom fraction 4 at -159.01°C and 1.15 bar with a flow rate of 30253 kmol/h. This fraction 4 (0.07% nitrogen, 91.17% methane, 5.90% ethane, 2.03% propane, 0.32% isobutane and 0.52% n-butane) is pumped by the pump PI to provide a fraction 39 at 4.15 bar and -158.86°C, then leaves the installation.
The column CI is equipped with the column bottom reboiler 16 which cools the stream 13 to obtain the stream 20.
The compressor Kl produces the compressed flow 5 at 37°C and 29 bar with a flow rate of 11341 kmol/h. This stream of fuel gas 5 (42.90% nitrogen and 57.09 methane) is split into a stream 40, which represents 3041 kmol/h, which leaves the installation, and a stream 6, which represents 8300 kmol/h, which is compressed in the compressor XKl.
The compressor XKl products the compressed stream 7 at 68.18°C and 39.7 bar. The stream 7 is cooled to 37°C in the water exchanger 24, then split into the streams 8 and 9.
The stream 8 (5700 kmol/h) is cooled in the exchanger El to yield the stream 25 at -74°C and 38.9 bar.
The stream 9 (2600 kmol/h) is cooled in the exchanger El to yield the stream 22 at -155°C and 38.4 bar. The latter is then expanded in the valve 23 to provide the stream 35 at -168°C and 5.1 bar.
The stream 25 is expanded in the expansion turbine XI which produces the fraction 10 at a temperature of
Bf

^—5^—
-139.7°C and a pressure of 8.0 bar. This fraction 10 is then heated in the exchanger El which produces the fraction 26 at a temperature of 32°C and a pressure of 7.8 bar.
The fraction 26 is fed to the compressor Kl on the medium-pressure stage 11. The compressor Kl and the expander XI have the following performance:
Denltrogenation unit
Power of compressor Kl 22007 kW
Power of expander XI 2700 kW
The use of the vessel V2 allows a saving of about 2000 kW on the power of the compressor Kl.
From these studies on the nitrogen-rich gas B, it is evident from the method according to the invention that:
the increase in temperature of the LNG leaving the liquefication method makes it possible to obtain an increase in LNG production capacity of 1.2% per °C,
the use of a denltrogenation column associated with liquefication of some of the fuel gas produced is far more effective than a final flash,
saturation of the power of the gas turbine coupled to the compressor Kl by use of the novel method makes it possible to achieve a significant gain in LNG production capacity,
the increase in the amount of fuel gas produced makes it possible to obtain an additional increase in the LNG production capacity,
the addition of the separating vessel V2 makes it possible to improve the load on the compressor Kl and to lower the cost of its use.
The following study relates to the use of the nitrogen-depleted gas A, in which the final flash unit produces no fuel gas.
^b

- 35 -
In a known way, natural gas containing very little nitrogen does not require the use of a final flash.
The LNG can then be produced directly at -160°C and be
sent for storage after expansion in a hydraulic
turbine, for example similar to X3: this is the highly
supercooled approach.
When the highly supercooled technique is chosen the
sources of fuel gas may be various:
gas from the top of the methane remover,
gas from the top of the condensate stabilization
column,
gas from the evaporation in the storage tanks,
gas from regeneration of the natural gas dryers,
etc.
It is then no longer possible to add a source of fuel gas without running the risk of having excess fuel gas. If there is a desire to increase the capacity of the LNG production line by increasing the temperature of the LNG produced using the liquefication method, it is necessary to set up a method that produces little or no fuel gas.
The method according to the invention makes it possible to achieve this objective. It makes it possible to increase the temperature of the LNG leaving the liquefication method and therefore to increase the flow rate of cooled LNG 4, produced for storage purposes.
This method is set out in figure 6, and was described above. For the same power of turbine coupled to the compressor Kl, the operating conditions will depend on the capacity of the liquefication unit. The case of the use of LNG 1 from an LNG production unit comprising 2 GE7 turbines is described hereinafter by way of example:
f

,-..36 -
The LNG 1 at a temperature of -147 °C is expanded to 2.7 bar in the hydraulic turbine X3 driving an electric generator, then undergoes a second expansion to 1.15 bar in the valve 18, and is fed to the flash vessel VI, in a mixture with LNG from the liquefication of the compressed fuel gas 5.
At the bottom of the vessel VI, the LNG is at -159.2 °C and 1.15 bar. It then leaves the installation and goes for storage.
The fuel gas 3, which is the first top fraction, is heated to 32°C in the exchanger El before being compressed to 29 bar in the compressor Kl, to possibly feed into the fuel gas network. In this instance, all of the fuel gas is sent to the compressor XKl to provide the compressed stream 7 at 41.5 bar. This stream is then cooled to 37°C in the water exchanger 24, and is then split into two flows 8 and 9.
The stream 8, which represents 79% of the stream 7, is cooled to -60°C before being fed to the turbine XI coupled to the compressor XKl. The turbine XI provides the expanded gas 10, at a pressure of 9 bar and a temperature of -127'C. This stream 10 is heated in the exchanger El to obtain a heated stream 26, at 32°C, then fed into the compressor Kl on the suction side of its third stage.
The stream 9, which represents 21% of the stream 7, is liquefied and cooled to -141°C in the exchanger El and returns to the flash vessel VI.
The use of the novel method has made it possible to increase by 15.82% the capacity of the liquefication sequence, for a reasonable on-cost.
ir

It must be understood that it is the combination of the recycling of the compressed fuel gas and of the expansion turbine cycle which leads to this highly surprising result.
For LNG production units of different size, the results are given in:
table 9, which corresponds to the characteristics of a unit operating according to the embodiment of the method of the invention as set out in figure 6,
table 10, given by way of comparison, which sets out the characteristics of an LNG refrigeration unit using the highly supercooled approach.
W

Units 1 GET
+ 1 6E6 2 GE7 3 6E7
LN6 1
Temperature °C -144 -147 -151
Flow rate kg/h 430862 556506 799127
Cooled LN6 4
Flow rate kg/h 430862 556506 799127
Specific lower heat value kJ/kg 49334 49334 49334
Nitrogen content mol% 0.10 0.10 0.10
Production of LNG 4, lower heat value GJ/h % 21256 100 27455 115.82 39424 110.87
Fuel gas 5
Flow rate kg/h 0 0 0
Specific lower heat value kJ/kg 0 0 0
Production of fuel gas 5, specific lower heat value GJ/h 0 0 0
Final flash unit
Power of compressor
Kl kW 24000 24000 23543
Power of expander XI kW 4719 4719 4850
Performance
Specific power of production of LNG 4 kJ/kg 1014 995 984
Ratio of power of Kl/production of LNG 4 0.0206 0.0202 0.0199
Additional production of LNG kg/h GJ/h 70489 3477 76010 3749 78381 3866
Table 9
4^

■39 *

Units 1 6E7
+ 1 6E6 2 6E7 3 6E7
LN6 1
Temperature °C -160 -160 -160
Flow rate kg/h 360373 480496 720746
Cooled LN6 4
Flow rate kg/h 360373 480496 720746
Specific lower heat value kJ/kg 49334 49334 49334
Nitrogen content mol% 0.10 0.10 0.10
Production of LNG 4, lower heat value GJ/h
O 17779 100.00 23705 100.00 35558 100.00
Fuel gas 5
Flow rate kg/h 0 0 0
Specific lower heat value kJ/kg 0 0 0
Production of fuel gas 5, specific lower heat value GJ/h 0 0 0
Final flash unit
Power of compressor Kl kW 0 0 0
Power of expander XI kW 0 0 0
Performance
Specific power of production of LNG 4 kJ/kg 973 973 973
Ratio of power of Kl/production of LNG 4 0.0197 0.0197 0.0197
Additional production of LNG kg/h GJ/h 0 0 0 0 0 0
Table 10
The increases in capacity for the use of an installation according to the method of the invention, by comparison with the highly supercooled approach, are as follows:
19.6% for an LNG unit using 1 GE6 turbine associated with one GE7 turbine,
15.8% for an LNG unit using 2 GE7 turbines, 10.9% for an LNG unit using 3 GE7 turbines.
The embodiment of the method according to the invention according to figure 6 also allows the production of

fuel gas, when this is desired. This eventuality is illustrated in a numerical example in table 11 below:

Units 1 GE7 + 1 GE6
LNG 1
Temperature °c -143
Flow rate kg/h 583534
Cooled LN6 4
Flow rate kg/h 567402
Specific lower heat value kJ/kg 49351
Nitrogen content mol% 0.06
Production of LNG 4, lower heat value GJ/h % 28002
118.13
Fuel gas 5
Flow rate kg/h 16132
Specific lower heat value kJ/kg 48659
Production of fuel gas 5, specific lower heat value GJ/h 785
Final flash unit
Power of compressor Kl kW 23888
Power of expander XI kW 3520
Performance
Specific power of production of LNG 4 kJ/kg 976
Ratio of power of Kl/production of LNG 4 0.0198
Additional production of LNG kg/h GJ/h 86906 4297
Table 11
When the production of fuel gas rises from 0 to 785 GH/h, it is then possible to increase the capacity by 18.13%, that is to say that 2.31% of the increase in capacity (18.13% minus 15.82%) are due to the production of fuel gas. This result is far more pronounced than the one obtained with a denitrogenation installation.
ka

Another embodiment according to the method of the invention, employing a denitrogenation column CI, is set out in figure 7, described above. Unlike in figure 6, this embodiment uses a separating vessel V2.
The LNG 1, of composition "A" obtained at -147°C at a pressure of 48.0 bar with a flow rate of 30885 kmol/h, is expanded to 2.7 bar and minus 147.63°C in the hydraulic turbine X3, then is expanded again to 2.5 bar and minus 148.33°C in the valve 18, to provide the expanded stream 2.
The stream 2 (30885 kmol/h) is mixed with the stream 35 (3127 kmol/h) to obtain the stream 36 (34012 kmol/h) at -149.00°C.
The stream 35 is made up of 3.17% nitrogen, 96.82% methane and 0.01% ethane.
The stream 36, which is made up of 0.38% nitrogen, 91.90% methane, 4.09% ethane, 2.27% propane, 0.54% isobutane and 0.82% n-butane, is separated in the vessel V2 into the second top fraction 12 (562 kmol/h) and the second bottom fraction 13 (33450 kmol/h).
The stream 12 (5.41% nitrogen, 94.57% methane and 0.02% ethane) is heated to 34 °C in the exchanger El, to provide a stream 37 which is fed, at 2.4 bar, to the compressor Kl to the medium-pressure stage 14.
The stream 13 (0.03% nitrogen, 91.85% methane, 4.16% ethane, 2.31% propane, 0.55% isobutane and 0.83% n-butane) is expanded in the valve 28 to obtain the stream 29 at -159.17°C and 1.15 bar, which is introduced into the separating vessel VI.
The vessel VI produces, at the top, the first top fraction 3 (2564 kmol/h) at -159.17°C. The fraction 3 (2.72% nitrogen, 97.27% methane and 0.01% ethane) is

-—*5
heated in the exchanger El to give the stream 41 at minus 32.21°C and 1.05 bar. The stream 41 is fed into the low-pressure suction side 15 of the compressor Kl,
The vessel VI produces the first bottom fraction 4 at -159.17°C and 1.15 bar with a flow rate of 30886 kmol/h. This fraction 4 (0,10% nitrogen, 91.40% methane, 4.50% ethane, 2.50% propane, 0.60% isobutane and 0.90% n-butane) is pumped by the pump PI to provide a fraction 39 at 4.15 bar and -159.02°C, then leaves the installation.
The compressor Kl produces the compressed stream 5 at 37°C and 29 bar with a flow rate of 13426 kmol/h. This fuel gas stream 5 (3.18% nitrogen, 96.81% methane and 0.01% ethane) is compressed in full in the compressor XKl, without producing fuel gas 40.
The compressor XKl produces the compressed stream 7 at 72.51°C and 42.7 bar. The stream 7 is cooled to 37°C in the water exchanger 24 and is then split into the streams 8 and 9.
The stream 8 (10300 kmol/h) is cooled in the exchanger El to give the stream 25 at -56°C and 41.9 bar.
The stream 9 (3126 kmol/h) is cooled in the exchanger El to give the stream 22 at -141°C and 41.4 bar. The latter stream is then expanded in the valve 23 to provide the stream 35 at -152.37°C and 2.50 bar.
The stream 25 is expanded in the expansion turbine XI which produces the fraction 10 at a temperature of -129.65°C and a pressure of 8.0 bar. This fraction 10 is then heated in the exchanger El which produces the fraction 26 at a temperature of 34°C and a pressure of 7.8 bar.

.-^
The fraction 26 is fed into the compressor Kl on the suction side of the medium-pressure stage 11. The compressor Kl and the expander XI have the following performance:

Denitrogenation unit Kl
Power of compressor Kl 23034 kW
Power of expander XI 2700 kW
The use of the vessel V2 allows a saving of about 1000 kW on the power of the compressor Kl.
Finally, from these studies on gas A, which is nitrogen-depleted, it is evident from the method according to the invention that:
the increase in the temperature of the LNG leaving the liquefication method makes it possible to obtain an increase in LNG production capacity of 1.2% per °C, this result being identical to the one obtained with gas A,
the use of a final flash (vessel VI) and the saturation of the power of the gas turbine driving the compressor Kl makes it possible, by virtue of the method of the invention, to obtain a significant gain in LNG production capacity, without producing fuel gas,
the production of fuel gas makes it possible to obtain an increase in the LNG production capacity. This gain is not insignificant and may prove to be a decisive factor,
the addition of the separating vessel V2 makes it possible to improve the load on the compressor Kl and to reduce the cost of using it.
^f

WE CLAIM :
1. A method for refrigerating a pressurized liquefied natural gas (1) containing methane and C2 and higher hydrocarbons, comprising a first step (I) in which step (la) said pressurized liquefied natural gas (1) is expanded to provide an expanded liquefied natural gas stream (2), in which step (lb) said expanded liquefied natural gas (2) is split into a relatively more volatile first top fraction (3) and a relatively less volatile first bottom fraction (4), in which step (Ic) the first bottom fraction(4) consisting of refrigerated liquefied natural gas is collected, in which step (Id) the first top fraction (3) is heated, compressed in a first compressor (Kl) and cooled to provide a first fiiel gas compressed fraction (5) which is collected, in which step (le) there is tapped off from the first compressed fraction (5) a second compressed fraction (6) which is then cooled, then mixed with the expanded liquefied natural gas stream (2), characterized in that the method comprises a second step (II) in which step (II) the second compressed fraction (6) is compressed in a second compressor (XKl) coupled to an expansion turbine (XI) to provide a third compressed fraction (7), in which step (lib) the third compressed fraction (7) is cooled, then split into a fourth compressed fraction (8) and a fifth compressed fraction (9), in which step (lie) the fourth compressed fraction (8) is cooled and expanded in the expansion turbine (XI) coupled to the second compressor (XKl) to provide an expanded fraction (10) which is then heated, then introduced into a medium pressure first stage (11) of the compressor (Kl), and in which step (lid) the fifth compressed fraction (9) is cooled, then mixed with the expanded liquefied natural gas stream (2)
2, The method as claimed in claim 1, wherein the expanded liquefied natural gas stream (2) is split, prior to step (lb), into a second top fraction (12) and a second bottom fraction (13), in that the second top fraction (12) is heated, then introduced into the first compressor (Kl) in an intermediate medium-pressure second stage(14) between the medium-pressure first stage (11) and a low-pressure stage (15), and in that the second bottom fraction (13) is split into the first top Suction (3) and the first bottom fraction (4).
46

3. The method as claimed in claim 1 or claim 2, wherein each compression step is followed by a cooling step.
4. The refrigerated liquefied natural gas (4) obtained by the method as claimed in any one of claims 1-3.
5. The fuel gas (5) obtained by the method as claimed in any one of claims 1-3.
6. An apparatus for refrigerating a pressurized liquefied natural gas, wherein the gas contains methane, C2 and higher hydrocarbons, the apparatus comprising:
(la) first means for expanding the pressurized liquefied natural gas for providing an expanded liquefied natural gas stream;
(lb) second means for splitting the expanded liquefied natural gas into a relatively more volatile first top fraction and a relatively less volatile first bottom fraction;
(Ic) a first collector for collecting the first bottom fraction comprised of refrigerated liquefied natural gas;
(Id) a heater for heating the first top fraction, a first compressor for compressing the heated top fraction and first cooling means for cooling the compressed top fraction for providing a ftiel gas compressed fraction, and a second collector for collecting the fiiel gas compressed fraction;
(le) a tap for tapping off the fuel gas compressed fraction from the second collector for providing a second compressed fraction; second cooling means for cooling the second compressed fraction and a mixer for mixing the second compressed fraction with the expanded liquefied natural gas stream;
(Ha) a second compressor for receivmg the second compressed fraction and for compressing the second compressed fraction, an expansion turbine coupled to the second compressor for providing a third compressed fraction from the compressor;
47

(nb) a first cooler for cooling the third compressed fraction; means for splitting the third compressed fraction into a fourth compressed fraction and a fifth compressed fraction;
(lie) a second cooler for cooling the fourth compressed fraction and communicating the fourth compressed fraction to the expansion turbine coupled to the second compressor for providing an expanded fraction; a heater for heating the expanded fraction; the first compressor having a medium-pressure first stage into which the heated expanded fraction is communicated;
(lid) a third cooler for cooling the fifth compressed fraction and a mixer for receiving the fifth compressed fraction and mixing the fifth compressed fraction with the expanded liquefied natural gas sfream.
7. The apparatus as claimed in claim 5, comprising:
a means for splitting the expanded liquefied natural gas stream into a second top fraction and a second bottom fraction prior to (lb) the second means for splitting;
means for heating and then for introducing the second top fraction into the first compressor in an intermediate medium-pressure second stage between the medium-pressure first stage and a low-pressure stage; and
means for splitting the second bottom fraction into the first top fraction and the first bottom fraction.
8. The apparatus as claimed in claim 6, comprising a first separating vessel for separating the first top fraction and the first bottom fraction.
9. The apparatus as claimed in claim 6, comprising a distillation column for separating the first top fraction and the first bottom fraction.
48

10. The apparatus as claimed in claim 7, comprising a separating vessel for splitting the
expanded liquefied natural gas stream into the second top fraction and the second bottom
fraction.
11. The apparatus as claimed in claim 8, wherein the distillation column comprises at least
one of a lateral or a column bottom reboiler; the distillation column having a plate and liquid is
tapped off the plate of the distillation column and is connected to pass through the reboiler,
a heat exchanger for heating the liquid passing through the reboiler, and a connection for reintroducing the heated liquid into the distillation column and a stage below the plate thereof; the expanded liquefied natural gas stream is communication with the heat exchanger to be cooled in the heat exchanger.
12. The apparatus as claimed in claim 10, wherein the heat exchanger s connected to the
first, expanded, fourth and fifth compressed fractions for causing cooling of the first top fraction
and of the expanded fraction and heating of the fourth and the fifth compressed fractions.
13. The apparatus as claimed in claim 11, wherein the heat exchanger communicates with a
second top fraction for heating the second top fraction in the heat exchanger.

Documents:

0950-chenp-2003 drawings.pdf

0950-chenp-2003 description(complete).pdf

0950-chenp-2003 form-2.pdf

0950-chenp-2003 claims.pdf

0950-chenp-2003 complete specification as granted.pdf

0950-chenp-2003 correspondence others.pdf

0950-chenp-2003 correspondence po.pdf

0950-chenp-2003 pct.pdf

0950-chenp-2003 power of attorney.pdf

0950-chenp-2003 form-1.pdf

0950-chenp-2003 form-18.pdf

0950-chenp-2003 form-3.pdf

0950-chenp-2003 form-5.pdf

0950-chenp-2003 petitions.pdf

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Patent Number

235124

Indian Patent Application Number

950/CHENP/2003

PG Journal Number

29/2009

Publication Date

17-Jul-2009

Grant Date

25-Jun-2009

Date of Filing

16-Jun-2003

Name of Patentee

TECHNIP FRANCE

Applicant Address

170 PLACE HENRI REGNAULT, LA DEFENSE 6, 92400 COURBEVOIE,

Inventors:

#	Inventor's Name	Inventor's Address
1	PARADOWSKI HENRI	32 RUE SERPENTE, F-95000 CERGY,

PCT International Classification Number

F25J1/02

PCT International Application Number

PCT/FR01/03983

PCT International Filing date

2001-12-13

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	00/16495	2000-12-18	France