EP0975923A1

EP0975923A1 - Method for liquefying a stream rich in hydrocarbons

Info

Publication number: EP0975923A1
Application number: EP98924120A
Authority: EP
Inventors: Rudolf Stockmann; Wolfgang FÖRG; Manfred BÖLT; Manfred Steinbauer; Christian Pfeiffer; Pentti Paurola; Arne Olav Fredheim; Oystein Sorensen
Original assignee: Linde GmbH; Den Norske Stats Oljeselskap AS
Current assignee: Linde GmbH; Equinor ASA
Priority date: 1997-04-18
Filing date: 1998-04-15
Publication date: 2000-02-02
Anticipated expiration: 2018-04-15
Also published as: EP0975923B1; NO995046D0; RU2212601C2; WO1998048227A1; AU735800B2; US6253574B1; NO310124B1; MY125139A; NO995046L; DE19716415C1; AU7643698A; DE59810225D1

Abstract

The invention relates to a method for liquefying a stream rich in hydrocarbons, especially a stream of natural gas, by the indirect exchange of heat with the refrigerants in a closed-circuit cascade of mixed refrigerants. According to the invention, said closed-circuit cascade of mixed refrigerants consists of at least 3 circuits of mixed refrigerants, with each circuit comprising different refrigerants. The first of the three mixed refrigerant circuits is used for pre-cooling (E1), the second for liquefying (E2), and the third for super-cooling (E3) the hydrocarbon-rich stream (1) to be liquefied. The method provided for in the invention reduces specific energy consumption and investment costs since the three circuits of mixed refrigerants are or can be optimally adjusted to the enthalpy temperature curves of the hydrocarbon-rich stream to be liquefied and the refrigerant mixtures.

Description

description

Process for liquefying a hydrocarbon-rich stream

The invention relates to a method for liquefying a hydrocarbon-rich stream, in particular a natural gas stream, by indirect heat exchange with the refrigerants in a refrigerant mixture circuit cascade.

On possibly necessary pretreatment steps of the hydrocarbon-rich stream before liquefaction, such as. B. acid gas and / or mercury removal, removal of aromatic components, etc., which are not the subject of the present invention, will not be discussed in more detail below.

Nowadays, most of the Baseload LNG plants are designed as so-called dual flow refrigeration processes. The refrigeration energy required for the liquefaction of the hydrocarbon-rich electricity or natural gas is provided by means of two separate refrigerant mixture circuits, which are connected to form a refrigerant mixture circuit cascade. Such a liquefaction process is e.g. B. known from GB-PS 895 094.

Furthermore, liquefaction processes are known in which the cooling energy required for the liquefaction is provided by means of a refrigerant circuit cascade, but not a refrigerant mixture circuit cascade; see e.g. B. LINDE reports from technology and science, issue 75/1997, pages 3 - 8. The refrigerant cycle cascade described therein consists of a propane or propylene, an ethane or ethylene and a methane refrigeration cycle. This refrigerant circuit cascade can be viewed as energetically optimized, but is comparatively complicated due to the 9 compressor stages.

Furthermore, such. As described in DE-AS 19 60 301, liquefaction processes are known in which the cooling energy required for the liquefaction is provided by means of a cascade consisting of a refrigerant mixture circuit and a propane precooling circuit. The object of the present invention is to provide a method for liquefying a hydrocarbon-rich stream, in particular a natural gas stream, which has a reduced specific energy consumption compared to such dual-flow refrigeration processes and thereby realizes a smaller plant size and is associated therewith enables lower investment costs.

This object is achieved in that the refrigerant mixture circuit cascade consists of at least 3 different refrigerant mixture circuits having different refrigerant compositions.

In the method according to the invention - called triple flow mixed refrigerant cycle - the refrigerant mixture circuit cascade consists of at least three separate refrigerant mixture circuits. These have different refrigerant compositions because they have to generate cold at different temperatures.

The first of the three refrigerant mixture cycles - the so-called Precooling Refrigerant Cycle (PRC) - is used to cool and partially or completely condense the refrigerant mixtures required for liquefaction and subcooling, as well as to pre-cool the hydrocarbon-rich stream. The second refrigeration mixture circuit - the so-called Liquefaction Refrigerant Qycle (LRC) - is used for partial or complete condensation of the refrigerant mixture required for subcooling and the condensation of the hydrocarbon-rich stream. The third refrigerant mixture circuit - the so-called subcooling refrigerator cycle (SRC) - is used to sub-cool the liquefied hydrocarbon-rich stream.

According to a further advantageous embodiment of the method according to the invention, a mixture of ethylene or ethane, propane and butane is used as the refrigerant for the first of the three refrigerant mixture cycles. This PRC mixed refrigerant circuit is used to provide refrigerant in a temperature range from ambient temperature to between approx. -35 and approx. -55 ° C. According to a further embodiment of the method according to the invention, a mixture of methane, ethylene or ethane and propane is used as the refrigerant for the second of the three refrigerant mixture cycles. For the third of the three refrigerant mixture circuits, a mixture of nitrogen, methane and ethylene or ethane is preferably used as the refrigerant. During the second or LRC The refrigerant mixture circuit provides cooling energy in a temperature interval of approx. -40 to approx. -100 ° C, the third or SRC refrigerant mixture circuit is used to provide the cooling down to approx. -85 and approx. -160 ° C.

The procedure according to the invention leads to a reduction in the specific energy consumption and the investment costs, since the three refrigerant mixture circuits are optimally adapted or can be adapted to the enthalpy-temperature curves of the hydrocarbon-rich stream to be liquefied and the refrigerant mixtures. This procedure, which is more efficient than a dual-flow refrigeration process, can either reduce the size of the liquefaction plant required, thereby reducing the cost of the plant, or increase the capacity of the hydrocarbon-rich electricity to be liquefied while the plant size remains the same.

The method according to the invention and further refinements of the same are explained in more detail with reference to FIGS. 1 to 5.

In the method according to the invention, the refrigerant preparation required for the liquefaction of the hydrocarbon-rich stream is carried out by at least three refrigerant mixture cycles. For the sake of clarity, a "P", "L" or "S" for PRC, LRC or SRC refrigerant mixture circuits is placed in front of the reference numerals of the individual refrigerant mixture circuits in FIGS. 1 to 5.

According to the method shown in FIG. 1, an optionally pretreated natural gas stream, which has a temperature between 10 and 40 ° C. and a pressure between 30 and 70 bar, is fed via line 1 to a first heat exchanger E1. In this heat exchanger E1, the natural gas flow is pre-cooled to a temperature between -35 and -55 ° C. against the refrigerant mixture in the expansion valve P13 of the first or PRC-refrigerant mixture circuit that is expanded in line P14.

The refrigerant mixture of the third or SRC refrigerant mixture circuit is fed to the heat exchanger E1 via line S5 at a temperature between 10 and 40 ° C and a pressure between 30 and 60 bar and cooled in the heat exchanger E1 against the previously mentioned refrigerant mixture in line P14 and partially condensed, the refrigerant mixture in line P 14 at a pressure between 2 and 6 bar evaporated. The refrigerant mixture of the SRC-refrigerant mixture circuit leaves the heat exchanger E1 via line S6 at a temperature between -35 and -55 ° C.

The refrigerant mixture of the second or LRC-refrigerant mixture circuit is fed to the heat exchanger E1 via line L5 with a temperature between 10 and 40 ° C and a pressure between 15 and 25 bar and condensed in the heat exchanger E1 against the refrigerant mixture of the PRC-refrigerant mixture circuit in line P14 . The refrigerant mixture of the LRC-refrigerant mixture circuit is withdrawn from the heat exchanger E1 at a temperature between -35 and -55 ° C.

The evaporated and superheated refrigerant mixture of the PRC refrigerant mixture circuit in line P14 contains, according to an advantageous embodiment of the process according to the invention, essentially 0 to 40 mol% ethylene or ethane, 30 to 40 mol% propane and 20 to 30 mol% butane. This refrigerant mixture is fed to the separator P1 at a pressure of 2 to 6 bar. The gaseous refrigerant mixture drawn off at the top of the separator P1 via line P2 is compressed in the compressor P3 to a pressure between 6 and 10 bar. The compressed refrigerant mixture in the cooler P4 is then cooled, preferably against sea water, against air or against an appropriate cooling medium, to a temperature between 10 and 40 ° C.

The refrigerant mixture is then fed to a further separator P6 via line P5. The gaseous fraction of the refrigerant mixture obtained at the top of the separator P6 is fed to the second compressor stage P8 and compressed there to a pressure between 10 and 20 bar. The liquid fraction from the separator P6 is pumped to a pressure between 10 and 20 bar by means of the pump P7, preferably a centrifugal pump, and then combined with the mixed refrigerant stream compressed in the compressor P8.

The compression of the refrigerant mixture of the first or PRC-refrigerant mixture circuit is preferably carried out in a two-stage, single-case centrifugal compression device which contains both the cooler P4 and the separator P6. In the case of very large quantities, an axial compression device can also be provided instead of the centrifugal compression device. The compressed refrigerant mixture of the PRC-refrigerant mixture circuit is condensed in the cooler P9, preferably against sea water or an appropriate cooling medium, and slightly subcooled up to a temperature range of 10 to 40 ° C. The refrigerant mixture is then fed via line P10 to the heat exchanger E1 and subcooled to a temperature of between -35 and -50 ° C against itself.

The evaporation temperature that can be achieved after the Joule-Thomson expansion in the expansion valve P13 - or alternatively in a expansion turbine - depends essentially on the degree of subcooling before expansion and on the evaporation pressure in the temperature range between -38 and -53 ° C.

As already mentioned at the beginning, the second or LRC refrigerant mixture circuit serves to liquefy the pre-cooled natural gas stream in line 2. The refrigerant mixture of this LRC / refrigerant mixture circuit essentially consists of a mixture of 5 to 15 mol% methane, 0 to 80 mol% Ethylene or ethane and 10 to 20 mole% propane. The precooled natural gas stream is fed to the heat exchanger E2 via line 2, cooled in it to a temperature between -80 and - 100 ° C. and then drawn off from the heat exchanger E2 via line 3.

The refrigerant mixture of the third or SRC-refrigerant mixture circuit is fed to the heat exchanger E2 via line S6 at a temperature between -35 and -50 ° C and condensed against the refrigerant of the LRC-refrigerant mixture circuit in line L10. The refrigerant mixture in line L10 evaporates at a pressure level between 1.5 and 6 bar. The cooled refrigerant mixture of the SRC-refrigerant mixture circuit is withdrawn from the heat exchanger E2 at a temperature between -80 and - 100 ° C via line S7.

The evaporated and overheated refrigerant mixture of the LRC-refrigerant mixture circuit in line L10 is fed to separator L1 at a pressure between 1.5 and 6 bar. The gaseous refrigerant mixture obtained at the top of the separator L1 is fed via line L2 to the compressor L3 and compressed therein to a pressure between 10 and 20 bar. The compressor E3 is preferably designed as a single-case axial or centrifugal compressor. Such cold suction compressors have the advantage that the suction The medium does not have to be warmed up to the ambient temperature before being drawn in, which saves heating space and thus the heat exchangers can be made smaller and cheaper.

The compressed refrigerant mixture of the LRC-refrigerant mixture circuit is cooled in the cooler L4, preferably against sea water or an appropriate cooling medium, to a temperature between 10 and 40 ° C. The refrigerant mixture drawn off from the cooler L4 via line L5 is, as already mentioned, liquefied in the heat exchanger E1, fed to the heat exchanger E2 via line L6 and subcooled to a temperature of between -80 and -100 ° C. against itself. The evaporation temperature of the refrigerant mixture after the Joule-Thomson expansion in the expansion valve L9 - or alternatively in a expansion turbine - is between -82 and -1 12 ° C.

The third or SRC refrigerant mixture circuit serves to sub-cool the liquefied hydrocarbon-rich stream or natural gas stream. This subcooling is useful or necessary so that no more than the required amount of flash gas after the expansion of the liquefied hydrocarbon-rich stream is produced in a downstream nitrogen removal unit.

The refrigerant mixture of the third or SRC refrigerant mixture circuit consists, according to a further advantageous embodiment of the method according to the invention, essentially of a mixture of 0 to 10 mol% nitrogen, 40 to 65 mol% methane and 0 to 40 mol% ethylene or 0 to 30 mol% ethane.

The liquefied hydrocarbon-rich stream fed via line 3 to the heat exchanger E3 is subcooled in the heat exchanger E3 to a temperature of -150 to -160 ° C. After this supercooling, the hydrocarbon-rich or natural gas stream is drawn off from the heat exchanger E3 via line 4 and expanded essentially to atmospheric pressure by means of a Joule-Thomson expansion in the expansion valve 5 - or alternatively in a expansion turbine.

The refrigerant mixture of the third or SRC-refrigerant mixture circuit supplied to the heat exchanger E3 via line S9 is subcooled in the heat exchanger E3 and then also subjected to a Joule-Thomson expansion in the expansion valve S10. Instead of the relief valve S10 can again an expansion turbine can be provided. Relaxation in the S10 expansion valve takes place at a pressure level between 2 and 6 bar. The evaporation of the refrigerant mixture in the heat exchanger E3 serves both to subcool the already liquefied hydrocarbon-rich stream and to self-subcool the refrigerant mixture of the SRC / refrigerant mixture circuit that has not yet expanded.

The evaporated and overheated refrigerant mixture of the SRC-refrigerant mixture circuit is fed to a separator S1 via line S11. The gaseous refrigerant mixture obtained at the top of the separator S1 is fed to a compressor S3 via line S2. In the compressor S3 the mixture of refrigerants is compressed to a pressure between 35 and 60 bar. The refrigerant mixture emerging from the compressor S3 is then cooled in the cooler S4, preferably against sea water or a corresponding cooling medium.

According to a further advantageous embodiment of the method according to the invention, each of the three refrigerant mixture circuits has a separator / storage tank P11, L7 or S8 downstream of the respective expansion valve P13, L9 or S10. In principle, these separators / storage tanks can also be provided at any other suitable location in the mixed-medium circuit.

The liquid fraction is drawn off from these separators / storage tanks P11, L7 and S8 via lines P16, L12 and S13 and fed to the respective vaporous top fraction (flash gas) of the mixture of refrigerants. This procedure ensures a good distribution of liquid and gas and thus a good heat transfer in the heat exchangers E1, E2 and E3, in particular if it is a so-called plate-fin type heat exchanger.

Control valves P15, L11 and S12 are provided in lines P16, L12 and S13. These control valves are used to regulate the liquid level within the separator / storage tank P 11, L7 or S8.

In the event of a plant shutdown, the control valves P15, L11 and S12 are closed so that the separators / storage tanks P11, L7 and S8 are filled with the refrigerant mixture of the respective refrigerant mixture circuit; for this it makes sense that the separators / storage tanks P11, L7 and S8 control valves - which are not shown in Figures 1 to 5 - are provided. This enables the refrigerant mixture to be stored at the coldest point in the respective refrigerant mixture circuit, which speeds up the start-up procedure when restarting. The separators / storage tanks P11, L7 and S8 should preferably be dimensioned in such a way that they can store the entire refrigerant mixture quantity of a refrigerant mixture circuit.

Further developing the method according to the invention, it is proposed that the compressors P8, P3, L3 and S3 be driven by only one gas turbine drive G; represented by the dash-dotted line (Note: Even if the designations of the compressors or compressor stages in FIGS. 3 to 5 have been changed compared to FIGS. 1 and 2, the dash-dotted line makes it clear that even in these embodiments of the method according to the invention, only one Compressor drive is required.).

FIG. 2 shows a liquefaction process for natural gas which is essentially identical to that of FIG. 1. However, the first, second and third or PRC, LRC and SRC refrigerant mixture circuits are only partially shown for the sake of clarity.

The hydrocarbon-rich stream or natural gas stream to be liquefied is fed to the heat exchanger E1 via line 1. At an appropriately selected temperature level, it is withdrawn from the heat exchanger E1 via line 1 'and fed to a separation column T1 which has a reboiler R1. This separation column T1 is used to separate heavy hydrocarbons which are drawn off at the bottom of the separation column T1 via line 8.

The natural gas depleted of heavy hydrocarbons at the top of the separation column T1 is in turn fed to the heat exchanger E1 via line 2 '. In this it is cooled further and fed as a partially condensed stream via line 2 "to a separator D. The liquid fraction obtained in the bottom of the separator D is fed as return to the top of the separation zone T1 by means of the pump P1 via line 2"'. The hydrocarbon-rich fraction obtained at the top of the separator is fed via line 2 to the heat exchanger E2 and liquefied therein. The liquefied hydrocarbon-rich stream then passes via line 3 into the heat exchanger E3, in which it is supercooled. The supercooled liquefied hydrocarbon-rich stream is then fed via line 4 to the separation column T2, and is passed through the column sump for the purpose of heating the reboiler R2 before the expansion in the expansion valve 5.

The separation column T2 is used to separate nitrogen and methane, a stream rich in these two components being drawn off at the top of the separation column T2 via line 6. This nitrogen and methane-rich stream drawn off via line 6 - the so-called tail gas - is warmed in the heat exchanger E4 against a partial stream of the hydrocarbon-rich stream drawn off at the top of the separator D, which stream is fed to the heat exchanger E4 via line 9 . The liquefied hydrocarbon-rich partial stream is then passed via line 10 and expansion valve 11 also to the separation column T2 - either on the same tray or any tray below the feed point of the hydrocarbon-rich stream in line 4.

The liquefied and supercooled natural gas drawn off from the bottom of the separation column T2 is fed to a storage device by means of the pump P2 via line 7.

Figure 3 shows a further advantageous embodiment of the method according to the invention. In this embodiment, compared to the embodiment shown in FIG. 1, the first or PRC refrigerant mixture circuit is modified. The LRC and SRC refrigerant mixture circuits, however, are identical to those as shown in Figure 1.

The compressed (P3) refrigerant mixture is cooled in the cooler P4 to a temperature between 10 and 40 ° C and liquefied in the process. It is then fed to the heat exchanger E1 via line P10 and supercooled in it. A partial flow of the supercooled mixture of refrigerants is expanded in the expansion valve P13 - or alternatively in an expansion turbine - and evaporated again in the heat exchanger E1. This mixed refrigerant flow is then fed via line P14 to the separator P1 at a pressure of 2 to 6 bar. The gaseous refrigerant mixture drawn off at the top of the separator P1 via line P2 is compressed in the compressor P3 to a pressure between 6 and 10 bar. A second partial stream of the liquefied and supercooled mixture of refrigerants is withdrawn from the heat exchanger E1 at a higher temperature level and expanded in the expansion valve P17 - or alternatively in a expansion turbine. For the sake of clarity, the separator / storage tank that can be provided after the expansion valve P17 and the corresponding control valves are not shown in the figure. After expansion P17, this partial flow of the mixture of refrigerants is also evaporated in the heat exchanger E1 and fed to the separator P6 via line P18. The gaseous refrigerant mixture drawn off at the top of the separator P6 via line P19 is likewise fed to the compressor P3 at an intermediate pressure stage.

After the two partial refrigerant mixture flows have been mixed and compressed to approximately 15 to 20 bar in the compressor P3, the compressed refrigerant mixture in the cooler P4 is cooled and liquefied, preferably against sea water, against air or against an appropriate cooling medium, at a temperature between 10 and 40 ° C.

This embodiment of the method according to the invention has the following advantages and disadvantages compared to the embodiment shown in FIG. 1:

The enthalpy-temperature diagram of the refrigerant mixture stream to be evaporated and heated in the PRC-refrigerant mixture circuit can be better adapted to the enthalpy-temperature diagrams of all streams to be cooled (natural gas stream, PRC, LRC and SRC refrigerant mixture circuit). The very large gas flow on the suction side of the compressor P3 is divided into two flows. This makes additional pipelines and control devices necessary. However, the dimensions of the pipelines are smaller. Overall, the energy consumption of this embodiment of the method according to the invention is lower.

FIGS. 4 and 5 show further advantageous refinements of the method according to the invention. In these embodiments, compared to the embodiment shown in FIG. 1, the first or PRC and / or the second or LRC refrigerant mixture circuit are modified. The SRC refrigerant mixture circuit, however, is identical to that as shown in Figures 1 and 3. For the sake of clarity, the SRC refrigerant mixture circuit is therefore not shown in full. In the embodiment shown in FIG. 4, the first or PRC refrigerant mixture circuit is also identical to that as shown in FIG. 3.

The compressed and then cooled in the cooler L4 to a temperature between 10 and 40 ° C refrigerant mixture of the second or LRC

The mixed refrigerant circuit is first fed to the heat exchanger E1 via line L5 and liquefied in it. The refrigerant mixture is then fed via line L6 to the heat exchanger E2 and subcooled there. A partial flow of the supercooled mixture of refrigerants is expanded in the expansion valve L9 - or alternatively in a expansion turbine - and evaporated in the heat exchanger E2. This partial refrigerant mixture stream is then fed to the separator L1 via line L10. The gaseous refrigerant mixture drawn off at the top of the separator L1 via line L2 is compressed in the compressor L3 to a pressure between 10 and 20 bar.

A second partial flow of the supercooled refrigerant mixture of the LRC-refrigerant mixture circuit is withdrawn from the heat exchanger E2 at a higher temperature level and expanded in the expansion valve L13 - or alternatively in a expansion turbine. For the sake of clarity, the separator / storage tank that can be provided after the expansion valve L13 and the corresponding control valves are not shown in the figure. After expansion L13, this partial flow of the mixture of refrigerants is also evaporated in the heat exchanger E2 and fed to the separator L15 via line L14. The gaseous refrigerant mixture drawn off at the top of the separator L15 via line L16 is likewise fed to the compressor L3 at an intermediate pressure stage.

After the mixing of the two partial refrigerant mixture flows described in the compressor L3, preferably against sea water, against air or against a corresponding cooling medium, the compressed refrigerant mixture in the cooler L4 is cooled to a temperature between 10 and 40 ° C.

This embodiment of the method according to the invention has the following advantages and disadvantages compared to the embodiment shown in FIGS. 1 and 3: Here, too, the enthalpy-temperature diagrams of the currents to be cooled and heated can be better matched to one another. It must be checked in each individual case whether the energy saving achievable by this embodiment of the method according to the invention justifies the additional effort for the more complex process control or system.

In the case of the embodiment of the method according to the invention shown in FIG. 5, only the second or LRC refrigerant mixture circuit is modified compared to the embodiment shown in FIG.

The compressed and subsequently liquefied and partially liquefied refrigerant mixture in the cooler L21 to a temperature between 10 and 40 ° C. is first fed to a separator L13 via line L5. The gaseous fraction of the refrigerant mixture is drawn off at the top of the separator L13 via line L6, liquefied in the heat exchanger E1 and subcooled in the heat exchanger E2. The refrigerant mixture is then expanded in the expansion valve L9 - or alternatively in a expansion turbine - and evaporated in the heat exchanger E2, after which it is fed to the separator L1 via line L10.

The liquid portion of the refrigerant mixture is withdrawn from the bottom of the separator L13 via line L14, subcooled in the heat exchanger E1 and brought to a less low temperature level in the heat exchanger E2. This liquefied and supercooled partial refrigerant mixture stream is then expanded in the expansion valve L15 - or alternatively in a expansion turbine -, likewise evaporated in the heat exchanger E2 and mixed with the evaporated partial refrigerant mixture stream in line L 10. For the sake of clarity, the separator / storage tank which can be provided after the expansion valve L15 and the corresponding control valves are not shown in FIG. 5.

The gaseous refrigerant mixture drawn off at the top of the separator L1 via line L2 is compressed in the compressor L3 to a pressure between 6 and 10 bar. This is followed, preferably against sea water, air or an appropriate cooling medium, by cooling the compressed mixture of refrigerants in cooler L4 to a temperature between 10 and 40 ° C. The refrigerant mixture is then fed to another separator L17 via line L16. The gaseous fraction of the refrigerant mixture at the top of the separator L17 is fed via line L18 to the second compressor stage L19 and compressed therein to a pressure between 12 and 25 bar. The liquid fraction from the separator L17 is pumped by means of the pump L20, preferably a centrifugal pump, to a pressure between 12 and 25 bar and then combined with the refrigerant mixture stream compressed in the compressor L19.

The compression of the refrigerant mixture of the second or LRC / refrigerant mixture circuit is preferably carried out in a two-stage, single-case centrifugal compression device which contains both the cooler L4 and the separator L17. In the case of very large quantities, an axial compression device can also be provided instead of the centrifugal compression device.

This embodiment of the method according to the invention has the following advantages and disadvantages compared to the embodiments shown in FIGS. 1, 2 and 3:

Also in the embodiment of the method according to the invention shown in FIG. 5, the enthalpy-temperature diagrams of the streams to be cooled and heated can be better matched to one another. Again, it must be checked in individual cases whether the energy saving achievable by this embodiment justifies the additional outlay for the more complex process control or system.

Under certain circumstances, it may make sense for the compressors and drives shown in FIGS. 1 to 5 to be provided twice in a liquefaction plant (eg 2 ^* 50%). With the redundancy provided, production can be maintained at least 50% even in the event of a machine malfunction.

Claims

claims

1. A method for liquefying a hydrocarbon-rich stream, in particular a natural gas stream, by indirect heat exchange with the refrigerants of a refrigerant mixture circuit cascade, characterized in that the refrigerant mixture circuit cascade consists of at least 3 different refrigerant mixture circuits having different refrigerant compositions.

2. A process for liquefying a hydrocarbon-rich stream according to claim 1, characterized in that the first of the 3 refrigerant mixture circuits of the pre-cooling (E1), the second refrigerant mixture circuit of the liquefaction (E2) and the third refrigerant mixture circuit of the supercooling (E3) of the hydrocarbon to be liquefied rich current (1) is used.

3. A process for liquefying a hydrocarbon-rich stream according to claim 1 or 2, characterized in that the refrigerant mixture of the first of the 3 refrigerant mixture circuits (P5, P10, ...) essentially 0 to 40 mol% of ethylene or ethane, 30 to Contains 40 mol% propane and 20 to 30 mol% butane.

4. A process for liquefying a hydrocarbon-rich stream according to one of the preceding claims, characterized in that the refrigerant mixture of the second of the 3 refrigerant mixture circuits (L5, L6, ...) essentially 5 to 15 mol% methane, 0 to 80 mol -% contains ethylene or ethane and 10 to 20 mol% propane.

5. A process for liquefying a hydrocarbon-rich stream according to one of the preceding claims, characterized in that the refrigerant mixture of the third of the 3 refrigerant mixture circuits (S5, S6, ...) essentially 0 to 10 mol% nitrogen, 40 to 65 mol -% methane and 0 to 40 mol% ethylene or 0 to 30 mol% ethane.

6. A method for liquefying a hydrocarbon-rich stream according to one of the preceding claims, characterized in that the pre-cooling (E1), the liquefaction (E2) and the subcooling (E3) of the hydrocarbon-rich stream (1) to be liquefied in at least 3 Heat exchangers (E1, E2, E3) take place and the relaxed refrigerant mixture of each of the 3 refrigerant mixture circuits is only passed through the last heat exchanger (E1, E2 or E3) before recompression (P3, L3, S3).

7. The method for liquefying a hydrocarbon-rich stream according to one of the preceding claims, characterized in that the compression of the refrigerant mixtures by means of cold-suction compressors (P3, L3, S3).

8. A method for liquefying a hydrocarbon-rich stream according to one of the preceding claims, characterized in that the compressors used for the compression of the refrigerant mixtures (P3, L3, S3) are driven by only one drive device (G), in particular a gas turbine drive device become.

9. A method for liquefying a hydrocarbon-rich stream according to one of the preceding claims, characterized in that in the event of a plant or process standstill at least the refrigerant mixture of one of the refrigerant mixture circuits in at least one separator / storage tank (P11, L7, S8), the or which are preferably arranged at the coldest point of each refrigerant mixture circuit, are stored temporarily.