The present invention relates to a process for liquefying natural gas in order to produce liquefied natural gas (LNG). Still more particularly, the present invention relates to liquefying natural gas that comprises mostly methane, preferably at least 85% methane, with its other main constituents being selected from nitrogen, and C-2 to C-4 alkanes, namely ethane, propane, and butane.
The present invention also relates to a liquefaction installation located on a ship or a support floating at sea, either in open sea or in a protected zone such as a port, or indeed an installation on land for medium and large units for liquefying natural gas.
Methane-based natural gas is either a by-product of an oil field, being produced in small or medium quantities, in general in association with crude oil, or else a major product of a gas field, where it is obtained in combination with other gases, mainly C-2 to C-4 alkanes, CO2, and nitrogen.
When small quantities of natural gas are associated with crude oil, the natural gas is generally treated and separated and then used on site as fuel in turbines or piston engines for producing electricity and for producing heat used in separation or production processes.
When the quantities of natural gas are large, or indeed very large, it is desirable to transport the gas so that it can be used in far-off regions, generally on other continents, and for this purpose the preferred method is to transport it in a cryogenic liquid state (−165° C.) substantially at ambient atmospheric pressure. Specialized transport ships known as methane tankers possess tanks of very large dimensions and extreme thermal insulation so as to limit evaporation during the voyage.
Gas is generally liquefied for transport purposes in the proximity of the site where it is produced, generally on land, and that operation requires large installations for reaching capacities of several thousands of (metric) tonnes (t) per year, with the largest presently existing plants combining three or four liquefaction units capable of producing 3 megatonnes (Mt) to 4 Mt per year and per unit.
That method of liquefaction requires large quantities of mechanical energy, with that mechanical energy generally being produced on site by taking a fraction of the gas in order to produce the energy needed for the liquefaction process. A portion of the gas is then used as fuel in gas turbines, in steam boilers, or in piston combustion engines.
Multiple thermodynamic cycles have been developed for optimizing overall energy efficiency. There are two main types of cycle. A first type is based on compressing and expanding a refrigerant fluid, with a change of phase, and a second type is based on compressing and expanding a refrigerant gas without a change of phase. The term “refrigerant fluid” or “refrigerant gas” is used to designate a gas or a mixture of gases circulating in a closed circuit and being subjected to stages of compression, possibly also of liquefaction, and to exchanges of heat with the surroundings, and then to stages of expansion, possibly also of evaporation, and finally to exchanges of heat with methane-containing natural gas for liquefying, which gas cools little by little to reach its liquefaction temperature at atmospheric pressure, i.e. about −165° C. for LNG.
Said first type of cycle, with a change of phase, is generally used for installations of large production capacity requiring a larger amount of equipment. Furthermore, refrigerant fluids, which are generally in the form of mixtures, are constituted by butane, propane, ethane, and methane, which gases are dangerous since in the event of a leak they run the risk of leading to explosions or large fires. Nevertheless, in spite of the complexity of the equipment required, they remain more efficient and they consume energy of about 0.3 kilowatt hours (kWh) per kilogram (kg) of LNG produced.
Numerous variants of that first type of process with phase change of the refrigerant fluid have been developed, and the various suppliers of technology or equipment have their own formulations of mixtures for association with specific pieces of equipment, both for so-called “cascade” processes in which the various refrigerant fluids used are single-component fluids and circulate in different flow circuit loops, and for so-called “mixed” cycle processes having multicomponent refrigerant fluid loops. The complexity of installations comes from the fact that in stages in which the refrigerant fluid is in the liquid state, and more particularly in separators and in connection pipes, it is necessary to install gravity collectors, also referred to herein as “separator tanks”, for gathering together the liquid phase and sending it to the cores of heat exchangers where it then vaporizes on coming into contact with the methane for cooling and liquefying, in order to obtain LNG.
The second type of liquefaction process, i.e. a process without a change of phase in the refrigerant gas, comprises a Claude cycle or an inverse Brayton cycle using a gas such as nitrogen. That second type of process presents advantages in terms of safety since the refrigerant gas in the cycle, generally nitrogen, is inert, and therefore not combustible, and that is very advantageous when installations are concentrated in a small area, e.g. on the deck of a floating support located in open sea, where such equipment is often installed on a plurality of levels, one above the other, and on an area that is reduced to the bare minimum. Thus, in the event of refrigerant gas leaking, there is no danger of explosion and it then suffices to reinject the lost fraction of refrigerant gas into the circuit. In contrast, the efficiency of that second type is lower since it generally requires energy of the order of 0.5 kWh/kg of LNG produced, i.e. about 20.84 kW days per tonne.
In spite of the lower energy efficiency of the liquefaction process without change of phase in the refrigerant gas, it is preferred to the process with change of phase since the process with change of phase is more sensitive to variations in the composition of the gas for liquefying, namely natural gas made up of a mixture in which methane predominates. In a cycle with change of phase of the refrigerant fluid, in order to ensure that efficiency remains optimized, the refrigerant fluid needs to be adapted to the nature and composition of the gas for liquefying and the composition of the refrigerant fluid might need to be modified over time as a function of modifications in the composition of the mixture of natural gas for liquefying as produced by the oil field. For such processes with change of phase, refrigerant fluids are used that are made up of a mixture of components.
More particularly, the object of the present invention is to provide an improved process for liquefying natural gas with change of phase.
More particularly, the present invention provides a method of liquefying natural gas mainly comprising methane, in which said natural gas for liquefying is liquefied by causing a stream of said natural gas to flow through at least one cryogenic heat exchanger in indirect contact with at least one first stream of first refrigerant fluid comprising a first mixture of components flowing in at least one first closed loop with change of phase, said first stream of first refrigerant fluid entering at a temperature substantially equal to the temperature T0 at which the natural gas enters into said first heat exchanger and at a pressure P1, passing through the heat exchanger as a co-current (parallel-flow) with said stream of natural gas and leaving it in the liquid state, said first stream of first refrigerant fluid in the liquid state being expanded in a first expander at the cold end of said first heat exchanger to the gaseous state at a pressure P′1 less than P1 and to a temperature T1 less than T0, and then leaving it via its hot end in the gaseous state and substantially at a temperature T0, said first stream of first refrigerant fluid in the gaseous state then being subsequently reliquefied at least in part and taken to the hot inlet of said first heat exchanger in order to constitute the feed of said first stream of first refrigerant fluid in the liquid state, which thus circulates in a closed circuit, the liquefaction of said first stream of first refrigerant fluid in the gaseous state comprising at least compression in a compressor followed by at least condensation in a condenser prior to being taken substantially to the pressure P1 at the hot end inlet of said first heat exchanger for exchanging heat with said first stream of first refrigerant fluid in the liquid state.
A problem with the above-defined process with change of phase lies in the composition of the refrigerant mixture changing over a cycle because a fraction of the lighter components of the refrigerant fluids tends to disappear and/or needs to be reinjected as explained below in the detailed description with reference to
More precisely, in such processes, it has been observed that the condensation of the gaseous phase downstream from the second condenser is not total. The fluid leaving the second condenser for recycling to the hot end of the first heat exchanger may be in a two-phase state with a small content of gaseous phase containing gases constituted by the lighter components of the refrigerant mixture, the liquid phase then having a higher concentration of heavier components. This small content of gas cannot be separated or recycled in simple manner and it therefore needs to be eliminated. This has the consequence of modifying the composition of the recycled liquid refrigerant fluid and thus leads to a rise in the lowest temperature T1 that can be reached during evaporation of the refrigerant liquid within the enclosure of the heat exchanger EC1. Unfortunately, said vaporization constitutes the main thermodynamic heat exchange involved during the cycle. In order to overcome that undesirable effect and conserve said lowest temperature T1, the pressure level needs to be increased, thereby leading to an increased consumption of energy, and consequently to a reduction in the overall efficiency of the installation, i.e. an increase in terms of kWh consumed per kg of liquefied gas produced.
U.S. Pat. No. 4,339,253 describes a phase change process in which the refrigerant fluid recycled to the hot end of a heat exchanger is recycled in the two-phase state.
EP 1 132 698 seeks to reliquefy gas evaporated from a liquid gas tank 4. For that purpose, it proposes mixing said evaporated gas with a portion of liquid gas within desuperheaters 32-38 and 44-46 in order to cause the gas to be put back into solution. In EP 1 132 698 there are no condensers at the outlets from the desuperheaters.
The object of the present invention is thus to provide a process for liquefying natural gas with change of phase as defined above, which process is improved, serving in particular to solve the above-specified problem.
To do this, the present invention provides a process for liquefying natural gas comprising a majority of methane, preferably at least 85% methane, the other components essentially comprising nitrogen and C-2 to C-4 alkanes, in which said natural gas for liquefying is liquefied by causing a stream of said natural gas at a pressure P0 greater than or equal to atmospheric pressure, P0 preferably being greater than atmospheric pressure, to flow in at least one cryogenic heat exchanger in indirect contact with at least one first stream of a first refrigerant fluid comprising a first mixture of compounds circulating in at least one first closed circuit loop with change of phase, said first stream of first refrigerant fluid entering said first heat exchanger via a first inlet at a “hot” end at a pressure P1 and at a temperature substantially equal to the inlet temperature T0 of the natural gas entering said first heat exchanger, the refrigerant passing through the heat exchanger as a co-current with said natural gas stream and leaving it via a “cold” end in the liquid state, said first stream of first refrigerant fluid in the liquid state being expanded by a first expander at the cold end of said first heat exchanger in order to return to the gaseous state at a pressure P′1 less than P1 and at a temperature T1 less than T0 inside said first heat exchanger at its cold end, then leaving the first heat exchanger via an outlet orifice at its hot end in the gaseous state and substantially at a temperature T0, said first stream of first refrigerant fluid in the gaseous state then being reliquefied at least in part and taken to the first inlet at the hot end of said first heat exchanger to constitute the feed of said first stream of first refrigerant fluid in the liquid state thus circulating in a closed circuit, the liquefaction of said first stream of first refrigerant fluid in the gaseous state comprising first compression in a first compressor followed by first partial condensation in a first condenser, and phase separation in a first separator tank separating a first liquid phase of first refrigerant fluid and a first gaseous phase of first refrigerant fluid, said first liquid phase of first refrigerant fluid at the low outlet from said first separator being taken by a pump substantially at the pressure P1 at least in part to said first inlet at the hot end of said first heat exchanger in order to constitute said first stream of first refrigerant fluid in the liquid state, said first gaseous phase of said first refrigerant fluid at the high outlet from said first separator being compressed substantially to the pressure P1 by a second compressor and then condensed at least in part in a second condenser, preferably after being mixed with at least one portion of said first liquid phase of first refrigerant fluid.
According to the present invention, said first gaseous phase of said first refrigerant fluid at the outlet from said second compressor is cooled in a desuperheater by coming into contact with a portion of said first liquid phase of first refrigerant fluid at the outlet from said first separator, said portion of first liquid phase of the first refrigerant fluid being micronized and vaporized, preferably being entirely vaporized, within said desuperheater, prior to said condensation in said second condenser.
Preferably, said portion of first liquid phase of first refrigerant fluid represents less than 10% by weight of the flow, more preferably 2% to 5% of the total flow of said first total liquid phase of first refrigerant fluid, so as to be vaporized entirely within said desuperheater, and so that the first refrigerant fluid at the outlet from said desuperheater is entirely in the gaseous phase prior to being at least partially condensed in said second condenser, the flow of said first liquid phase portion of first refrigerant fluid being adjusted with the help of at least one control valve.
The vaporization of said first and second streams of first refrigerant fluid by said first and second expanders constitutes the main part of the heat exchange within said first cryogenic heat exchanger by cooling said first and second streams of first refrigerant fluid in the gaseous state within said first heat exchanger and causing heat to be absorbed, and cooling said natural gas streams to the temperature T1 less than T0, and thus cooling said first and second streams of first refrigerant fluid in the liquid state.
The micronizing (also known as “atomizing”) of said first liquid phase of first refrigerant fluid increases the contact area between the particles of liquid and the gas into which said liquid phase is sprayed, thereby enhancing its evaporation and absorption of heat, and cooling of said first gaseous phase of first refrigerant fluid. Micronizing a controlled quantity constituting a small portion of said first liquid phase of first refrigerant fluid thus enables it to be converted entirely to the gaseous state and cools said first gaseous phase of first refrigerant fluid, which remains entirely in the gaseous state. The pre-cooling of said gaseous phase of first refrigerant fluid by mixing with a portion of the liquid phase micronized within the desuperheater is advantageous in that it enables a larger fraction of the gaseous phase to condense in said second condenser, and possibly enabling all of it to condense.
In addition, said first gaseous phase of said first refrigerant fluid at the outlet from said first separator tank is more easily condensed in said second condenser after mixing with at least one portion of said first liquid phase of first refrigerant fluid after micronizing and vaporizing, since said resulting gaseous phase is condensable at a temperature that is higher and at a pressure that is lower than the temperature and pressure required in the prior art, and thus requiring less power to drive said second compressor.
In a first variant implementation, as described more completely below with reference to
The above implementation (
In a second variant implementation that is described more fully below with reference to
Still more particularly, said natural gas leaving the cold end of said first heat exchanger at a temperature substantially equal to T1 is cooled and at least partially liquefied in at least one second cryogenic heat exchanger, in which said natural gas for liquefying is liquefied by causing the stream of said natural gas to flow in indirect contact with at least one first stream of a second refrigerant fluid comprising a second mixture of compounds flowing in at least one second closed circuit loop with phase change, said second stream of refrigerant fluid entering into said second heat exchanger at a first inlet at the “hot” end of said second heat exchanger at a temperature substantially equal to T1 and at a pressure P2, passing through said second heat exchanger as a co-current with said stream of natural gas, and leaving it at a temperature in the liquid state at a “cold” end of said second heat exchanger, said first stream of second refrigerant fluid in the liquid state being expanded by a third expander at the cold end of said second heat exchanger in order to return to the gaseous state at a pressure P′2 less than P2 and at a temperature T2 less than T1 within said second heat exchanger beside its cold end, and then leaving via an outlet orifice at the hot end of said second heat exchanger in the gaseous state substantially at a temperature T1, said first stream of second fluid in the gaseous state then being partially reliquefied and taken to the inlet at the hot end of said second heat exchanger in order to constitute the feed of said first stream of second cooling fluid in the liquid state thus circulating in a closed loop, the liquefaction of said first stream of second refrigerant fluid in the gaseous state comprising compression to a pressure P2 by a third compressor and then cooling substantially to T0 in a cooling heat exchanger, with said first stream of second cooling fluid in the gaseous state then being taken to an inlet at the hot end of said first heat exchanger through which it passes in order to leave it via its cold end in the partially liquefied state substantially at the temperature T1, and then being subjected to phase separation in a third separator tank separating a liquid phase of second refrigerant fluid from a gaseous phase of second refrigerant fluid, the liquid phase of second refrigerant fluid at the low outlet from said third separator being taken substantially at the temperature T1 and the pressure P2 to said first inlet at the hot end of said second heat exchanger in order to form said first stream of second refrigerant fluid in the liquid state, said gaseous phase of said second refrigerant fluid at the high outlet from said third separator being taken to a second inlet at the hot end of said second heat exchanger substantially at the temperature T1 and at the pressure P2 in order to form a second stream of second refrigerant fluid passing through said second heat exchanger in the gaseous state and leaving at the cold end of said second heat exchanger prior to leaving from an outlet orifice at the hot end of said second heat exchanger in order to be taken to said third compressor with said first stream of second fluid in the gaseous state, preferably mixed together therewith.
In a preferred implementation, said natural gas leaving the cold end of said second heat exchanger at a temperature substantially equal to T2 and partially liquefied is cooled and fully liquefied at a temperature T3 lower than T2 in at least one third cryogenic heat exchanger, in which said natural gas flows in indirect contact as a co-current with at least one third stream of second refrigerant fluid fed by said second stream of second refrigerant fluid in the gaseous state leaving the cold end of said second heat exchanger substantially at the temperature T2 and at the pressure P2, said third stream of second refrigerant fluid passing in the gaseous state through said third heat exchanger as a co-current with said stream of liquefied natural gas and leaving it substantially in the gaseous state and being expanded by a fourth expander at the cold end of said third heat exchanger to return to the gaseous state at a pressure P2′ less than P2 and at a temperature T3 less than T2 within said third heat exchanger beside its cold end, and then leaving it via an orifice at its hot end in the gaseous state and substantially at a temperature T2 in order subsequently to be taken to an orifice at the cold end of said second heat exchanger in order to leave it via an orifice at the hot end of said second heat exchanger in order to be taken to said third compressor together with said first stream of second fluid in the gaseous state, preferably mixed together therewith.
According to another particular characteristic, said expanders comprise valves with an opening percentage that is suitable for being controlled in real time.
Still more particularly, the compounds of the natural gas and of the refrigerant fluids are selected from methane, nitrogen, ethane, ethylene, propane, butane, and pentane.
Still more particularly, the composition of the natural gas for liquefying lies within the following ranges for a total of 100% of the following compounds:
Still more particularly, the composition of the refrigerant fluids lies within the following ranges for a total of 100% of the following compounds:
Still more particularly, the temperatures have the following values:
Still more particularly, the pressures have the following values:
Advantageously, a process of the invention is performed on board a floating support.
The present invention also provides an installation on board a floating support for performing a process of the present invention, the installation being characterized in that it comprises:
More particularly, an installation of the present invention further comprises:
More particularly, an installation of the present invention further comprises:
Other characteristics and advantages of the present invention appear in the light of the following detailed description of various embodiments given with reference to the following figures:
Natural gas flows in ducts of coil shape Sg passing successively through three cryogenic heat exchangers in series EC1, EC2, and EC3. Natural gas enters at AA into the first cryogenic heat exchanger EC1 at a temperature T0, greater than or substantially equal to ambient temperature and at a pressure P0 lying in the range 20 bar to 50 bar (2 megapascals (MPa) to 5 MPa). The natural gas leaves at BB at T1=−50° C. approximately. In this heat exchanger EC1, the natural gas is cooled but it remains in the gaseous state. Thereafter, it passes at CC into a second cryogenic heat exchanger EC2 of temperature lying in the range T1=−50° C. approximately at its hot end CC to T2=−120° C. approximately at its cold end DD. In this second heat exchanger EC2, all of the natural gas becomes liquefied as LNG at a temperature T2=−120° C. approximately. Thereafter, the LNG passes at EE into a third cryogenic heat exchanger EC3. In this third heat exchanger EC3, the LNG is cooled to the temperature T3=−165° C., thereby enabling the LNG to be discharged in the bottom portion at FF, and then enabling it to be depressurized at GG so as to be able finally to store it in liquid form at ambient atmospheric pressure, i.e. at an absolute pressure of about 1 bar (i.e. about 0.1 MPa). Throughout that passage of the natural gas along the circuit Sg through the various heat exchangers, the natural gas is cooled, delivering heat to the refrigerant fluid, which in turn become heated by vaporizing as described below and needs to be subjected continuously to complete thermodynamic cycles with change of phase in order to be able to extract heat continuously from the natural gas entering at AA.
Thus, the passage of the natural gas is shown on the left of the PFD where said natural gas flows downwards along the circuit Sg, its temperature decreasing on moving downwards, from a temperature T0 that is substantially ambient at the top at AA, to a temperature T3 of about −165° C. at the bottom at FF; the pressure being substantially equal to P0 down to the level FF of the cold outlet from the cryogenic heat exchanger EC3.
In
In the right-hand portion of the PFD, there are shown the thermodynamic cycles to which the refrigerant fluids are subjected in the two loops, as described below.
In conventional manner, the cryogenic heat exchangers EC1, EC2, and EC3 are constituted by at least two fluid circuits that are juxtaposed but that do not communicate fluids between each other, the fluids flowing in said circuits exchanging heat all along their passage through the said heat exchanger. Numerous types of heat exchanger have been developed for various industries, and in the context of cryogenic heat exchangers, two main types are known: firstly coil heat exchangers and secondly heat exchangers using brazed aluminum plates, and commonly referred to as “cold boxes”.
The description of the invention with reference to
The process has a first loop referred to as a primary loop or a primary mixed refrigerant (PMR) loop that is made up as follows. A flow d1 of a first stream of the first refrigerant fluid enters the first cryogenic heat exchanger EC1 at its cold end AA at a point AA1 where its temperature is substantially equal to T0 and at a pressure P1, where P1 lies for example in the range 1.5 MPa to 10 MPa. Said first refrigerant fluid passes in the liquid state into the first heat exchanger EC1 in a first pipe of coil shape S1. The first stream of refrigerant fluid leaves the heat exchanger EC1 at BB at a temperature T1 of −50° C. approximately, prior to being directed to a first expander D1 that is constituted by a servo-controlled valve, said valve being in communication at BB1 with the inside of the enclosure 6 of the first heat exchanger EC1 beside the cold end of the heat exchanger EC1. Because of its expansion to a pressure P′1 less than P1, where P′1 lies in particular in the range 2 MPa to 5 MPa, the liquid of the first refrigerant fluid vaporizes, absorbing heat from the natural gas circuit Sg and heat from the other circuits of the first loop within the first heat exchanger as described below, and also, where appropriate, heat from the duct forming part of the second loop as described below, or indeed other loops when using multiple loop circuits referred to as multiple mixed refrigerant (MMR) circuits.
The first refrigerant fluid in the gaseous state at BB1 passes through the enclosure as a countercurrent and leaves the enclosure of the first heat exchanger EC1 at AA3 at its hot end AA, while still in the gaseous state and substantially at a temperature T0. Said first stream of refrigerant fluid in the gaseous state is then reliquefied and taken to the hot inlet AA1 of said first heat exchanger EC1 in order to constitute the feed of a said first stream of first refrigerant fluid in the liquid state to the inside of the duct S1, thus circulating around a closed circuit.
For this purpose, the stream of the first refrigerant fluid leaving the cold end of the enclosure of the first heat exchanger EC1 at AA3 while in the gaseous state is initially compressed from P′1 to P″1, where P″1 lies in the range P′1 to P1, in a first compressor C1, and is then condensed in part in a first condenser H0. The two-phase mixture of the first refrigerant fluid leaving the first condenser H0 is subjected to phase separation in a first separator tank R1. A first liquid phase of the first refrigerant fluid is extracted from the bottom of the first separator tank R1 and redirected as a flow d1a and at a pressure substantially equal to P1 by means of a pump PP to the inlet of a second condenser H1. A gas phase of the first refrigerant fluid is extracted from the top end of the separator tank R1 and is compressed substantially to the pressure P1 as a flow d1b by a second compressor C1A, the temperature at the outlet from said compressor being about 80° C. to 90° C. To facilitate condensation of this gaseous phase d1b, it is mixed with the liquid phase d1a prior to introducing the two-phase mixture d1 that is obtained into the second condenser H1.
In the prior art embodiment shown in
In that primary loop, the composition of the refrigerant mixture is generally determined in terms of alkane components C1, C2, C3, and C4 in the manner described below in order to reach a lowest temperature T1 of about −50° C. However, once a lighter portion of the components has been eliminated, the composition of the mixture changes and its lowest temperature T1 then becomes −40° C. or −45° C., or even −35° C. This results in a drop in the efficiency of the primary loop and thus in a drop in the overall efficiency of the liquefaction process.
In an improved variant of
The adaptations to the primary loop of the present invention as described below with reference to
The embodiments of
At the cold outlet BB from the cryogenic heat exchanger EC1, the natural gas at temperature T1 is partially liquefied and then passes into the second cryogenic heat exchanger EC2, which it leaves at the temperature T2 while partially liquefied, prior to being cooled and liquefied completely at a temperature T3 in the third cryogenic heat exchanger EC3. A second mixture of refrigerant fluid flows in a second closed circuit loop with phase change as follows. The second refrigerant fluid reaches the hot end CC of EC2 at CC1 while in the liquid state at the temperature T1 and at the pressure P2, where P2 lies for example in the range 2.5 MPa to 10 MPa. The second refrigerant fluid in the liquid state passes through the second heat exchanger EC1 in a coil-shaped duct S2 as a countercurrent to the natural gas fluid in Sg. This first stream of second refrigerant fluid in the liquid state as a flow d2a is then expanded in an expander D2 at the cold end DD of the second heat exchanger EC2 at a point DD1 to a pressure P′2 less than P2 and at a temperature T2 less than T1, inside the enclosure of the second heat exchanger EC2. Thereafter, this first stream of second refrigerant fluid leaves the second enclosure via an orifice CC3 at the hot end of the second heat exchanger EC2, while in the gaseous state and substantially at a pressure P′2 and a temperature T1. This stream of second refrigerant fluid in the gaseous state is then compressed from P′2 to P2 in a compressor C2 that it leaves at a temperature lying in the range 80° C. to 100° C., approximately, prior to being cooled in a temperature cooling heat exchanger H2 that it leaves while still in the gaseous state and at a temperature substantially equal to T0 (20° C. to 30° C.) This second refrigerant fluid gas is then taken at AA4 to the hot end AA of the first cryogenic heat exchanger EC1 in order to be cooled on passing through it in a coil-pipe type S1B that it leaves at BB3 at the cold end BB of the first heat exchanger EC1 at a temperature T1=−50° C. approximately and in a multiphase state, i.e. a partially-liquefied state, as a flow d2 in order to be separated in a second separator tank R2, where it is separated into a liquid phase and a vapor phase. The liquid phase is sent as a flow d2a via CC3 to the hot end CC of the second heat exchanger EC2 in order to constitute the feed of said first stream of the second refrigerant fluid in the liquid state within the coil S2 for the purpose of performing a new cycle as described above. The vapor phase flow d2b leaving the second separator tank R2 is likewise taken to the hot end CC of the second heat exchanger EC2 at substantially T1 and substantially P2 in order to feed via CC2 another coil-shaped duct S2A within the second heat exchanger EC2. The gaseous stream d2b of the second refrigerant fluid leaves via DD3 in the vapor state at a pressure substantially equal to P2 and at a temperature T2=−120° C. approximately in order to be taken to the hot end EE of the third cryogenic heat exchanger EC3, still at T2=−120° C. approximately, within which heat exchanger it is cooled in a coil-shaped duct S3. The refrigerant fluid leaves the duct S3 at FF while still in the gaseous state at a pressure of substantially P2 and at a temperature T3=−165° C. approximately prior to being expanded to P′2 less than P2 in an expander D3 directly within the enclosure EC3 at a cold end via FF1 in order to leave it at its hot end via EE1 at approximately a pressure P2 and a temperature T2=−120° C. and being taken to the cold end of the second enclosure EC2 via DD2. This second stream d2b of second refrigerant fluid in the gaseous state is then in a mixture with the first stream d2a of the second refrigerant fluid vaporized to the gaseous state on expanding in the expander D2 at DD1, the mixture of the two gases leaving the second heat exchanger EC2 as a flow d2=d2a+d2b via CC3 in order to perform a new cycle through the compressor C2 and the cooler E2, as described above.
In
In
In
In
A desuperheater DS of this type is sold by the supplier Fisher-Emerson (France).
In
In
This implementation of
The fact that the first stream or flow d1′ and the second stream or flow d1″ of the first refrigerant fluid in the liquid state respectively leaving the second condenser H1 and the pump PP as described above are not mixed together before passing through the first heat exchanger EC1, but rather pass through the first heat exchanger EC1 in two separate ducts S1 and S1A is also advantageous, since the two streams present different compositions of the first refrigerant fluid, and they are also at different pressures. Thus mixing them would lead to instabilities that are more problematic than those in the prior art. Nevertheless, it is possible to control the mixing of said two liquid streams using appropriate regulation systems, e.g. control valves, but that would go against the simplicity and the reliability desired in an installation of this type.
In
In
In the variant implementation of
The implementation of
The condensers H0 and H1 and the cooler H2 may be constituted by water heat exchangers, e.g. exchanging heat with sea or river water, or cold air heat exchangers of the cooling tower type, known to the person skilled in the art.
The compositions of the first and second refrigerant fluids are associated with the technologies used in terms of cryogenic heat exchangers and condensers, and manufacturers and suppliers all recommend their own compositions. However these compositions are also closely associated with the composition of the natural gas that is to be liquefied, and the components of the refrigerant fluids are advantageously adjusted over time whenever the characteristics of the natural gas change in significant manner.
By way of example, the first refrigerant fluid operating in a loop in the heat exchanger EC1, and thus at ordinary temperature T0 (20° C. to 30° C.) down to a lowest temperature T1 of about −50° C., is constituted by the following mixture:
Likewise, the second refrigerant fluid operating in a loop in the heat exchangers EC1, EC2, and EC3, and thus from T1=−50° C. approximately, down to a lowest temperature of T3=−165° C. approximately, is constituted by the following mixture:
The mechanical power consumed for an annular production of 2.5 mega tonnes per year (Mt/y) in the installation as a whole is of the order of 85 megawatts (MW):
These powers involved by the processes of the invention are of the same order and have substantially the same distribution as the powers involved in the prior art. In contrast, said processes of the invention are much more stable and reliable, and as a result provide an optimized industrial technique.
The invention is described above in the context of two-loop processes, comprising a “hot” first loop corresponding to the circuits S1-S1A-S1B operating in the heat exchanger EC1 (−50° C.), and a “cold” second loop corresponding to the circuits S2-S2A-S3 operating in the heat exchangers EC2 (−50° C.=>−120° C.) and EC3 (−120° C.=>−165° C.). However, similar processes exist in which the “hot” loop is identical, but the “cold” loop is replaced by two independent loops each having its own refrigerant fluid, in general a second loop operating in the heat exchanger EC2, i.e. from −50° C. to −120° C., while the third loop operates in the heat exchanger EC3, i.e. from −120° C. to −165° C. In all of these processes, and regardless of the type of cryogenic heat exchanger, the “hot” loop corresponding to the heat exchanger EC1 remains substantially the same as that described with reference to
Number | Date | Country | Kind |
---|---|---|---|
1256888 | Jul 2012 | FR | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/FR2013/051593 | 7/4/2013 | WO | 00 |