METHOD AND SYSTEM FOR THE RE-LIQUEFACTION OF BOIL-OFF GAS

Description

Field of the invention

[0001] The present invention relates to a method and system for re-liquefying boil-off gas by processing a stream of hydrocarbon gas, a stream of cryogenic fluid, and a stream of boil-off gas. More particularly, the present invention relates to controlling the flow rate of the stream of cryogenic fluid based in part on the flow rates of the streams of hydrocarbon gas and boil-off gas.

Background of the invention

[0002] Natural gas is a key source of energy for the world economy; it is estimated that natural gas supplies approximately one-fifth of global energy needs. This compares to one-third and one-quarter for oil and coal respectively. As is generally the case with bulk energy commodities, natural gas reserves do not lie near the major areas of demand, and so natural gas must be transported and traded internationally. Approximately 30% of natural gas produced globally is traded on the world market.

[0003] The two principal methods for transporting natural gas are: a) transporting in gaseous form in pipelines; and b) transporting in liquid form as liquefied natural gas (LNG) in transport vessels.

[0004] To transport natural gas in liquid form as LNG, the gas must be liquefied (i.e. changed from a gaseous state to a liquid state). The liquefaction of LNG is an energy intensive process and so is more economical for long distance transport; in particular across oceans. As a result, LNG accounts for nearly three-quarters of long-distance natural gas trade. Due to the energy required for its liquefaction, LNG contains a large quantity of embodied cold energy which is released when it is re-gasified (i.e. changed from its liquid state following liquefaction back into its gaseous state).

[0005] The use of LNG in recent years has risen significantly as a share of both gas production and trade. Global LNG trade has more than doubled since 2000, while pipeline trade has risen by only around one-third.

[0006] In the Atlantic natural gas market, pipeline trade and local gas production have a dominant market share, which tends to favour inter-basin trading; particularly in the UK where LNG import terminals have seen a downturn in utilisation over the past few years, with cargoes being diverted to the Asia-Pacific in search of higher prices. In such a competitive market, the flexibility and efficiency of LNG import terminals is particularly important. The owners of LNG infrastructure such as LNG import terminals therefore seek further improvements in handling, storage and re-gasification of LNG.

[0007] LNG import terminals typically receive LNG from a transport vessel, such as a specially designed cargo ship, and pump it into large capacity low-pressure storage tanks, where it is stored at cryogenic temperatures (around -163 °C). When market conditions are favourable, LNG is pumped to high pressure, warmed and vaporised before being exported on the gas network. The export rate, or nomination, is highly dependent on gas price.

[0008] In recent years, the UK LNG market has experienced volatile gas prices, leading to fluctuating export and significant periods of zero export nomination from LNG terminals. Figure 6 shows an example profile of a year's send-out from an LNG terminal. These conditions require a liquefaction plant to be as flexible and efficient as possible to enable operators to have maximum control over when and how much LNG is exported, whilst maximising storage capacity and longevity.

[0009] In any thermal process, efficiency losses occur when heat is allowed to flow in to or out of the process. Due to the low temperatures involved in cryogenic systems, a significant source of uncontrolled heat is the ambient environment. This heat may enter the system through pipe and vessel walls. In an LNG infrastructure the ingress of heat results in the loss of LNG through evaporation. This is commonly known in the industry as boil-off and the resulting vapour phase as boil-off gas (BOG).

[0010] It is widely understood that over long periods, a significant proportion of LNG may be lost through boil-off. In a well-insulated LNG tank, a typical boil-off rate may be 0.05% of the volume per day. However, this rate may increase up to 3 times or more depending on the design and operational requirements of the plant. The boil-off rate may be even higher during transients such as unloading of an LNG cargo.

[0011] Furthermore, LNG is a multi-component fluid (typically composed of methane, ethane, nitrogen, propane and butane) and it is widely understood that during the storage and handling of such multi-component cryogenic fluids, boil-off may result in a change in their component concentration. This is the result of the different volatilities of the component fluids. Heat ingress will cause the components to evaporate at different rates. The more volatile components (with lower saturation temperatures for a fixed pressure) will tend to evaporate first and the liquid phase will therefore become more concentrated in the less volatile components. This represents an additional problem as strict regional standards for natural gas composition must be respected. Over time, evaporation leads to a costly degradation of the LNG stock. The ratio of the calorific value and the density of the gas (the Wobbe index) must subsequently be controlled by the reinjection of LNG components, typically propane and nitrogen.

[0012] It is therefore of critical importance to carefully manage LNG stocks to minimise losses through boil-off.

[0013] The higher the rate of heat flow into the process the faster the rate of boil-off. In an LNG infrastructure, the rate of heat flow is minimised primarily by insulating the infrastructure from the surrounding ambient environment. For example, a typical LNG tank is well insulated in order to minimise the ingress of heat. Although particular to the infrastructure design and operation, further limitation of boil-off may typically be achieved through management of tank levels, optimised timing of deliveries, and cooling of key systems.

[0014] For example, during unloading of LNG to an import terminal, the transfer of heat from warm pipework to the incoming LNG causes the boil-off rate to increase. This may result in a peak in the rate of boil-off. Often it is preferable to maintain the pipework at cryogenic temperatures by active cooling. This allows the plant to remain in a state of readiness, improving reactivity. This may be achieved most effectively by continuously running LNG through the pipelines. This represents a trade-off, inducing a higher continuous boil-off rate in order to maintain the pipework at operational temperature.

[0015] It is widely appreciated that boil-off cannot be completely eliminated. However, the loss of LNG stock through boil-off may be eliminated by re-liquefying the boil-off gas and returning it to storage in its liquid form. The full volume of LNG is thus retained and the degradation of the LNG composition is avoided, thus increasing the longevity of the stock. Re-liquefaction is achieved by compressing, cooling and in some cases expanding the boil-off gas. Typically, cooling is achieved using closed-loop refrigeration cycles with a refrigerant fluid. Sometimes the boil-off gas may be employed as a refrigerant fluid by returning a portion of cooled or re-liquefied boil-off gas to the system to perform cooling. The process of re-liquefaction is energy intensive and represents a high operating cost.

[0016] Where re-liquefaction is too costly, all or a portion of the boil-off gas may be utilised to offset the operating costs of the plant. Examples include extracting useful heat or work from combustion. The benefits of this solution vary according to market conditions as the boil-off gas used in this way is diverted from the gas market. In some cases there may not be sufficient energy requirement in the plant and it is often more cost effective to import energy from external sources.

[0017] Boil-off gas may alternatively be sent out on the local or regional gas network, but compressing the gaseous boil-off gas to the required pressure for the network is costly. To reduce energy requirements the boil-off gas is often condensed into a stream of supercooled LNG. The resulting liquid may be pumped to higher pressure and gasified to achieve the required network pressure. Alternatively, the boil-off gas may be re-liquefied in heat exchange with a stream of LNG before being mixed in its liquid phase. In any case, since boil-off gas is richer in the more volatile components of LNG, mixing with LNG allows the criteria for gas composition to be respected. However, during this process, up to two units or more of re-gasified LNG must be added to one unit of boil-off gas. This often results in a minimum rate of continuous export that is considerably greater than the actual boil-off rate. This minimum send-out rate limits the flexibility of the plant to respond to market conditions. Moreover, since the export of LNG is required for this process, continuous operation of the re-gasification plant is necessary.

[0018] The advantages of boil-off gas re-liquefaction are evident. Re-liquefaction represents a means of addressing both the loss of LNG over time through boil-off and the degradation of the LNG stock. The operator is afforded maximum control over when and how much gas is exported; crucially, the operator is not required to export gas during unfavourable market conditions.

[0019] However, the operating costs of re-liquefaction processes are usually prohibitive, especially in large infrastructures with large amounts of pipework, where high levels of boil-off occur, and where active cooling is employed. These operating costs arise from the work required by the process, which is generally provided by electric motors.

[0020] A re-liquefaction process requires the input of work to compress the working fluid. The fluid is then cooled by a cold source. Those skilled in the art will recognise that the quantity of work required to achieve the required cooling is dependent on the temperature of the cold source. Where the cold source is at ambient temperature, a greater quantity of work is required. Where the cold source is below ambient temperature, for example at cryogenic temperature, the quantity of work required is greatly reduced.

[0021] One source of cold in an LNG import terminal is the re-gasification of LNG, which is heated from approximately -163°C to near-ambient temperature. The cold recovered from this process is often dissipated as waste. However, if this cold is recovered and recycled in a liquefaction process, the electrical consumption of the process may be reduced by as much as two thirds. This approach has been adopted in the design of nitrogen liquefiers and air separation plants integrated into LNG infrastructure, a number of which are in operation in Japan and Korea.

[0022] US 4329842 describes a system for utilising cold energy from regasification of LNG at an LNG vaporising plant. LNG is taken from an LNG source ship and passed through to a pipeline via a liquid air generating plant where it is used generate liquid air for subsequent use in a power generation system.

[0023] However, it has been established that the re-liquefaction of boil-off gas is of primary importance during unfavourable market conditions, at a time when the cold from re-gasification of LNG is not available. This "anti-phase" between the requirement for and the availability of cold has hitherto prevented the cold from LNG re-gasification being used to re-liquefy boil-off gas during such periods.

[0024] US 3400547 discloses a process for utilising a cryogenic fluid to facilitate generation and transport of LNG. Cold energy from evaporation of LNG at a market site Is used to liquefy nitrogen, which is transported to the field. Here, cold energy from the liquefied nitrogen is used to liquefy natural gas to form LNG, which is transported back to the market site.

[0025] US2007/0186563 discloses a method of cold recovery in a cold compressed natural gas cycle. Cold energy from cold compressed natural gas in a cavern is used to liquefy air for storage, with the resulting natural gas being distributed via pipeline. Natural gas may be drawn from the pipeline, cooled using cold energy form the liquefied air, and stored in the cavern.

[0026] Neither of these documents offers a solution to the problems described above of how to deal efficiently with the problem of boil-off. Accordingly, an improved method and system is required for liquefying boil-off gas which overcomes the above-mentioned problems.

[0027] US 3768271 B discloses a method and plant for storing and transporting a liquefied combustible gas.

[0028] JP 2002 295799 A discloses an LNG storage tank and a liquid nitrogen tank connected to an air separator. Liquid nitrogen of an appropriate quantity is pumped to a heat exchanger for generating gaseous nitrogen from the liquid nitrogen tank while reliquefying BOG from the LNG storage tank. At the same time, gaseous nitrogen boil-off gas is liquefied by gasifying LNG from the storage tank.

Summary of the invention

[0029] The invention is defined by the appended claims.

[0030] A method for liquefying boil-off gas according to the invention is disclosed in claim 1.

[0031] By performing the steps of the method according to the invention, an improved method of re-liquefying boil-off gas is achieved through effective recovery, storage and recycling at a later time of the cold energy released during re-gasification of a hydrocarbon gas. In some circumstances, the energy required to re-liquefy boil-off gas using the method of the invention may be more than halved compared with conventional methods. The energy requirements for the method of the invention are low enough to be implemented in existing hydrocarbon gas infrastructure. Thus, the method provides a cost-effective technique which improves flexibility of managing the export of hydrocarbon gas according to market conditions; increases the longevity of storage; and effectively increases the storage volume of the hydrocarbon gas tanks by ensuring hydrocarbon gas used in continuous cooling is not lost. It is particularly advantageous in that it reduces the work required for the re-liquefaction of boil-off gas by the recycling of cold available on site that would otherwise be unavailable when required.

[0032] A particular advantage of the present invention is that cold from the re-gasification of hydrocarbon gas may be recovered, stored and utilised in a process for the re-liquefaction of boil-off gas independently of the rate and time of cold recovery.

[0033] In particular, by storing a liquefied cryogenic fluid in a fluid store, and by controlling the flow rate of the cryogenic fluid into and out of the store, it is possible to make use of cold recovered from regasification of the liquefied hydrocarbon gas whilst that process is taking place; store the recovered cold in the fluid store; and utilise it when required to re-liquefy boil-off gas. The steps of storing and controlling the cryogenic fluid enable energy to be transferred between two processes even if those processes are not taking place at the same time.

[0034] The present invention is particularly useful at LNG import terminals and any other LNG storage infrastructure with a regasification plant, where the cold from re-gasification of LNG may be recovered and utilised for the re-liquefaction of boil-off gas. However, it would also be applicable to boil-off from other high volume cryogenic storage systems where the cold from regasification is periodically available.

[0035] It should be noted that, for convenience, the description and claims refer to the cryogenic fluid, boil-off gas and hydrocarbon gas in their gaseous and liquefied forms. It should be understood that in each case, the same fluid is being referred to albeit in a different phase. For instance, the invention mentions a liquefied cryogenic fluid. It will be understood that this is the liquefied state of the stream of gaseous cryogenic fluid which is also mentioned.

[0036] It should also be noted that, for consistency of nomenclature, the cryogenic fluid is described as such in both its gaseous and liquefied forms irrespective of the temperature of the fluid. Hence, in certain circumstances the gaseous cryogenic fluid may be at near-ambient or above ambient temperatures. Regardless, it is referred to in this application as a cryogenic fluid because it is utilised to transfer heat to and from fluids at cryogenic temperatures.

[0037] Finally, whilst it is appreciated that 'cold' is merely the absence of energy, rather than a form of energy itself, it is convenient to use the expression 'cold energy' in a discussion of energy transfer in a cryogenic energy system because it is typically cold temperatures which are sought to be preserved and ingress of heat energy which is sought to be excluded. The skilled reader will appreciate that in this sense, 'cold energy' is a convenient fiction for describing this technology and is analogous to the transfer and preservation of heat energy in non-cryogenic systems.

[0038] The method may further comprise the step of processing the stream of gaseous boil-off gas and the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store such that:

a) the stream of liquefied hydrocarbon gas undergoes a phase change from a liquefied hydrocarbon gas to a gaseous hydrocarbon gas; and

b) the stream of gaseous boil-off gas undergoes a phase change from a gaseous boil-off gas to a liquefied boil-off gas;

wherein the step of processing comprises transferring heat from the stream of gaseous boil-off gas to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store.

[0039] This method is advantageous because it permits the boil-off gas to be re-liquefied whilst regasification of the liquefied hydrocarbon gas is taking place, as well as at a later time using the cold stored in the cryogenic fluid. This further improves the efficiency of the process because cold energy from regasification can be used to cool boil-off gas directly, whereas cooling using the cryogenic fluid may be reserved for when regasification is not taking place.

[0040] In the case mentioned above, the steps of: a) transferring heat from the stream of gaseous cryogenic fluid to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store; and b) transferring heat from the stream of gaseous boil-off gas to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store; may be concurrent.

[0041] When the steps are concurrent, the cold energy from regasification is used to re-liquefy boil-off gas and cool and liquefy the cryogenic fluid for later use. This may be particularly preferable if there is a plentiful supply of cryogenic fluid; stocks of liquefied cryogenic fluid in the store are low; and/or a long delay is expected until the next regasification of hydrocarbon gas.

[0042] The step of processing the stream of gaseous cryogenic fluid and the stream of liquefied hydrocarbon gas may further comprise one or both of the steps of: expanding the stream of gaseous cryogenic fluid after heat transfer; and compressing the stream of gaseous cryogenic fluid prior to heat transfer. The stream of gaseous cryogenic fluid may be compressed to a supercritical pressure.

[0043] In certain circumstances, the transfer of heat itself is sufficient to effect the change of phase from liquid to gas and vice versa. In these circumstances one fluid will enter a heat exchange (for example) in the liquid phase and exit in the gaseous phase whilst the other will enter the heat exchange in the gaseous phase and exit in the liquid phase. However, in practice this is not always possible or convenient, and the process is made more efficient by one or both of compressing and expanding one or more of the fluids before and after heat transfer. In the present case it has been found advantageous to expand the gaseous cryogenic fluid after heat transfer to achieve liquefaction and compress the gaseous cryogenic fluid before heat transfer.

[0044] The method may further comprise the steps of passing the stream of liquefied hydrocarbon gas through first and second branches. In that case, the step of transferring heat from the stream of gaseous cryogenic fluid to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store may further comprise:

transferring heat to a stream of liquefied hydrocarbon gas in the first branch from the stream of gaseous cryogenic fluid prior to compression; and

transferring heat to a stream of liquefied hydrocarbon gas in the second branch from the stream of gaseous cryogenic fluid after compression.

[0045] Preferably, the method further comprises combining the streams of gaseous hydrocarbon gas in the first and second branches.

[0046] Passing the stream through first and second branches enables the cold energy transferred from the liquefied hydrocarbon gas to be used in more than one place. In particular, it is advantageous for the gaseous cryogenic gas to undergo initial cooling, prior to compression for example, and then to undergo subsequent cooling to liquefy the cryogenic gas. By providing first and second streams of liquefied hydrocarbon gas, both stages of cooling can be achieved by the cold energy from the regasification process.

[0047] It will be understood that hydrocarbon gas finds many uses in commercial and residential properties, as well as in industry and the plants themselves. Preferably, the method further comprises the step of delivering the stream of gaseous hydrocarbon gas to a recipient such as one or more of: a hydrocarbon pipe network; a power station; and a consumer of gaseous hydrocarbon gas.

[0048] Preferably, the method further comprises the step of collecting the stream of gaseous boil-off gas, such as by collecting the boil-off gas from the liquefied hydrocarbon gas store and/or collecting the boil-off gas from a store, conduit, or collection point coupled to the liquefied hydrocarbon gas store. Boil-off can occur wherever liquefied hydrocarbon gas is present and at risk of being warmed through insufficient insulation. The skilled person is familiar with methods for collecting this boil-off from all over an infrastructure, wherever it occurs - even very far from the tank - and thus efficiencies can be increased.

[0049] The step of transferring heat from the stream of gaseous cryogenic fluid to the stream of liquefied hydrocarbon gas from the hydrocarbon gas store may be direct, or it may comprise transferring heat from the stream of gaseous cryogenic fluid to a heat transfer fluid in a closed-loop refrigeration circuit and cooling the gaseous cryogenic fluid to a temperature below the saturation temperature of the liquefied hydrocarbon gas; and transferring heat from the heat transfer fluid in the closed-loop refrigeration circuit to the stream of liquefied hydrocarbon gas.

[0050] Heat transfer takes place indirectly via one or more refrigeration circuits (or equivalent), wherein cold from a source stream is passed to one or more intermediate streams of heat transfer fluid before reaching Its destination stream. In the method according to the invention, cold from the stream of liquefied hydrocarbon gas (i.e. the source stream) is passed to a closed-loop refrigeration circuit before reaching the stream of gaseous cryogenic fluid (i.e. the destination stream). The closed-loop refrigeration circuit may also involve expanding and compressing the heat transfer fluid to obtain the required temperatures.

[0051] In cases where heat from the stream of gaseous boil-off gas is transferred to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store, the step of transferring heat from the stream of gaseous boil-off gas to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store may further comprise:

transferring heat from the stream of gaseous boil-off gas to the heat transfer fluid in the closed-loop refrigeration circuit; and

transferring heat from the heat transfer fluid in the closed-loop refrigeration circuit to the stream of liquefied hydrocarbon gas.

[0052] It will be appreciated that the destination stream for the cold energy which passes from the source stream through the one or more intermediate streams may be more than one stream. In the preferred example, cold energy is transferred not only to the stream of gaseous cryogenic gas, but also to the stream of gaseous boil-off gas.

[0053] Preferably, the method further comprises processing a stream of ambient air to form the stream of gaseous cryogenic fluid. This may involve, for example, filtering the stream of ambient air to remove moisture, carbon dioxide and/or hydrocarbons; and/or compressing the stream of ambient air. Air is particularly advantageous due to its abundance. This permits a readily available supply of gaseous cryogenic fluid for use on demand.

[0054] Preferably, the method further comprises passing the stream of liquefied cryogenic fluid through a separator prior to it entering the liquefied cryogenic fluid tank to separate any residual vapour phase from the stream of liquefied cryogenic fluid, and returning the residual vapour phase to the stream of gaseous cryogenic fluid.

[0055] It will be appreciated that cryogenic fluid may suffer boil-off within the infrastructure itself, in particular before the liquefied cryogenic fluid enters the store. Moreover, the liquefaction of cryogenic fluid may not be 100% efficient, and there may be cryogenic fluid in the vapour or gas phase even after the stream has been processed. In these circumstances, separating the vapour or gas phase and returning it to the gaseous stream of cryogenic fluid is particularly advantageous because the efficiency of the liquefaction process is improved.

[0056] Preferably, the method further comprises pumping the stream of liquefied cryogenic fluid from the liquefied cryogenic fluid store to increase its pressure prior to the step of transferring heat from the stream of gaseous boil-off gas to the stream of liquefied cryogenic fluid from the liquefied cryogenic fluid store.

[0057] Preferably, the step of transferring heat from the stream of gaseous boil-off gas to the stream of liquefied cryogenic fluid from the liquefied cryogenic fluid store results in a second stream of gaseous cryogenic fluid. In that case, the method may further comprise the step of expanding the second stream of gaseous cryogenic fluid to extract work from the stream.

[0058] The step of expanding the second stream of gaseous cryogenic fluid to extract work from the second stream may be performed in a single-stage expansion device, a two-stage expansion device, or a multi-stage expansion device.

[0059] Preferably the method further comprises super-heating the second stream of gaseous cryogenic fluid prior to one or more stages of expansion. The heat source for super-heating the cryogenic fluid may be ambient air. It may otherwise be any heat source from a co-located process with a temperature of up to 500°C, for instance.

[0060] Preferably the method further comprises the step of converting the work extracted from the second stream into electricity.

[0061] By extracting work from the gaseous cryogenic fluid used to re-liquefy the boil-off gas, the work required by the process (such as the work done in compressing the gaseous cryogenic fluid and/or pumping the liquefied cryogenic fluid) may be offset. Steps of increasing the pressure of the liquefied cryogenic fluid, and expanding and superheating the cryogenic fluid increase the efficiency by which work may be extracted from the stream. This work may be converted to electricity using an electric generator.

[0062] A system for liquefying boil-off gas according to the Invention is disclosed in claim 2.

[0063] Most of the advantages associated with a system according to the present invention have already been described above in connection with the method according to the invention. Hence, for conciseness, they are not repeated here.

[0064] The first and second arrangements of conduits may be arranged such that heat is transferred from the stream of gaseous boil-off gas passing through the second arrangement of conduits to the stream of liquefied hydrocarbon gas passing through the first arrangement of conduits.

[0065] The third arrangement of conduits may comprise a compressor for compressing the stream of gaseous cryogenic fluid. In that case, the first arrangement of conduits may comprise a first branch and a second branch. The first branch is preferably arranged such that heat is transferred to a stream of liquefied hydrocarbon gas passing through the first branch from the stream of gaseous cryogenic fluid passing through the third arrangement of conduits at a first heat exchange region upstream of the compressor. The second branch is preferably arranged such that heat is transferred to a stream of liquefied hydrocarbon gas passing through the second branch from a stream of gaseous cryogenic fluid passing through the third arrangement of conduits at a second heat exchange region downstream of the compressor.

[0066] The first and second branches may bifurcate from a single conduit upstream of the first and second heat exchange regions, and recombine to a single conduit downstream of the first and second heat exchange regions.

[0067] The source of boil-off gas may be the first store, and/or a store, conduit, or collection point coupled to the first store.

[0068] The first and third arrangements of conduits are arranged such that heat is transferred between the first and third arrangements of conduits via a closed-loop refrigeration circuit comprising a heat transfer fluid passing through a fifth arrangement of conduits. According to the invention, the fifth and third arrangements of conduits are arranged such that heat is transferred from the stream of gaseous cryogenic fluid passing through the third arrangement of conduits to the heat transfer fluid passing through the fifth arrangement of conduits. The fifth and first arrangements of conduits are arranged such that heat is transferred from the heat transfer fluid passing through the fifth arrangement of conduits to the stream of liquefied hydrocarbon gas passing through the first arrangement of conduits.

[0069] If the first and second arrangements of conduits are arranged such that heat is transferred from the stream of gaseous boil-off gas passing through the second arrangement of conduits to the stream of liquefied hydrocarbon gas passing through the first arrangement of conduits, then the first and second arrangements of conduits may also be arranged such that heat is transferred between the first and second arrangements of conduits via the closed-loop refrigeration circuit. In that case, the fifth and second arrangements of conduits may be arranged such that heat is transferred from the stream of gaseous boil-off gas passing through the second arrangement of conduits to the heat transfer fluid passing through the fifth arrangement of conduits.

[0070] If the first arrangement of conduits comprises first and second branches, then the second branch may be arranged such that heat is transferred from the heat transfer fluid passing through the fifth arrangement of conduits to the stream of liquefied hydrocarbon gas passing through the second branch.

[0071] Preferably, the stream of gaseous cryogenic fluid air, and the third arrangement of conduits further comprises one or both of: a filtration system for removing moisture, carbon dioxide and/or hydrocarbons from a stream of ambient air; and a compressor for compressing a stream of ambient air.

[0072] The third arrangement of conduits may further comprise a separator upstream of the second store for extracting any residual vapour phase from the stream of liquefied cryogenic fluid passing through the third arrangement of conduits prior to entering the second store, and a return conduit arranged to direct the residual vapour phase extracted from the stream of liquefied cryogenic fluid to the stream of gaseous cryogenic fluid passing through the third arrangement of conduits.

[0073] Preferably, the second and fourth arrangements of conduits are arranged such that heat is transferred between the second and fourth arrangements of conduits at a third heat exchange region and the fourth arrangement of conduits further comprises a pump upstream of the third heat exchange region for pumping the stream of liquefied cryogenic fluid passing through the fourth arrangement of conduits prior to it passing through the third heat exchange region.

[0074] Preferably, the third heat exchange region is configured such that heat is transferred from the stream of gaseous boil-off gas passing through the second arrangement of conduits to the stream of liquefied cryogenic fluid passing through the fourth arrangement of conduits to produce a second stream of gaseous cryogenic fluid. In that case, the fourth arrangement of conduits further comprises an expansion device for expanding the second stream of gaseous cryogenic fluid and extracting work from the second stream of cryogenic fluid.

[0075] The expansion device may be a single-stage expansion device, a two-stage expansion device, or a multi-stage expansion device.

[0076] Preferably, the fourth arrangement of conduits is coupled to one or more super-heaters, wherein each super-heater is either upstream of the first stage of the expansion device or between stages of the expansion device. In one example, if the expansion device has three expansion stages, and the fluid passing through is superheated before passing through each stage, then the system will comprise a first superheater upstream of the first stage, a second superheater between the first and second stages, and a third superheater between the second and third stages. In this context, the terms 'upstream' and 'between' do not preclude the possibility of there being other components (valves, an suchlike) between a superheater and a respective stage. It will be appreciated that not every stage need have a corresponding superheater. For a given arrangement in an expansion device, any number of superheaters may be provided in any arrangement appropriate for the circumstances.

[0077] In a preferred embodiment, the first, second, third and fourth arrangements of conduits are arranged such that heat is transferred between the first and third arrangements of conduits, between the second and fourth arrangements of conduits, at a single heat exchange region.

[0078] It will be appreciated that further efficiencies, both in terms of heat transfer as well as space, may be achieved by providing a single heat exchange region to for effecting more than one transfer of heat between two different streams. The heat exchange region may be provided by a single heat exchange (i.e. such that heat transfer is effected directly), or by a plurality of heat exchangers .i.e. such that heat transfer is effected via the aforementioned closed-loop refrigeration circuit.

[0079] More preferably, the first, second, third and fourth arrangements of conduits are arranged such that heat is transferred between the first and second arrangements of conduits at the single heat exchange region.

[0080] The closed-loop refrigeration circuit mentioned above may operate using one of a single-phase Brayton cycle and a dual-phase Rankine cycle.

[0081] The heat transfer fluid may be any fluid with the appropriate thermo-dynamic properties with respect to the saturation temperatures of the hydrocarbon gas and the cryogenic fluid. For example, nitrogen or propane may be used, both of which are typically available at a hydrocarbon gas terminal.

[0082] The cryogenic fluid mentioned above may be one of nitrogen or air, preferably ambient air. Nitrogen is typically available at a hydrocarbon gas terminal and requires minimal processing before it can be used, whereas air is abundant.

[0083] Finally, it should be noted that the liquefied hydrocarbon gas mentioned herein is preferably Liquefied Natural Gas (LNG). LNG is the predominant kind of hydrocarbon gas in current supply, and therefore the present invention finds particular utility with LNG. However, the present invention may be implemented with any hydrocarbon gas wherein the re-liquefaction of boil-off in any application where a hydrocarbon which is normally in its gaseous phase under ambient conditions is stored as a cryogenic liquid in large quantities and then re-gasified for use.

Brief description of the drawings

[0084] Preferred embodiments of the invention will now be described with reference to the accompanying drawings, in which:

figure 1 is a diagram of a system according to a first embodiment of the invention;

figure 2 is a diagram of a system according to a second embodiment of the invention;

figure 3 is a diagram of a system according to a third embodiment of the invention;

figure 4 is a diagram of a system according to a fourth embodiment of the invention;

figure 5 is a diagram of a system according to a fifth embodiment of the invention; and

figure 6 is a graph depicting an example of the gas send-out of an LNG terminal over a year.

Detailed description of the invention

[0085] The present inventors have previously disclosed, in patent application number WO200709665, a cryogenic energy storage system which stores energy using a cryogenic fluid. The present inventors have also described, in UK patent application number 1305640.3, an efficient method of cooling within an air liquefaction processes using cold recovery from adjacent LNG re-gasification process. Both of these disclosures are helpful, but not necessary, for putting the present invention into practice.

[0086] A first embodiment of the present invention uses a cryogenic fluid, such as liquid air or liquid nitrogen, to store the cold from the re-gasification of LNG. A system diagram of the first embodiment is presented in figure 1.

[0087] During re-gasification, the LNG is pumped to high pressure and split into two streams, whereby the first stream is warmed and vaporised in heat exchange with the cryogenic fluid in its gaseous phase; and the second stream is warmed and vaporised in heat exchange with a refrigerant, typically nitrogen, in a closed-loop refrigeration cycle.

[0088] The two, now gaseous, streams are then merged into a single stream of gaseous natural gas for export. The re-gasified natural gas is sent, as known in the art, to a recipient, which may form part of the LNG infrastructure or be an external infrastructure or customer. Examples include, but are not limited to: a gas sendout station, a pipe network, a power station, and a bottling plant. The stream may be split and sent to multiple recipients.

[0089] For this process, the cryogenic fluid is supplied in its gaseous form at near ambient temperature and is pre-cooled in heat exchange with the first stream of LNG; compressed using a compressor to supercritical pressure; sub-cooled in heat exchange with the refrigerant in the closed-loop refrigeration cycle; and expanded, whereby it condenses to form a cryogenic liquid.

[0090] The closed-loop refrigeration cycle is used to cool the cryogenic fluid to a temperature below the saturation temperature of LNG. The closed-loop system may be a single-phase Brayton cycle wherein the heat transfer fluid is compressed with a compressor; cooled in counter-flow heat exchange with the second stream of LNG; expanded in an expander; and warmed in heat exchange with the pre-cooled, compressed gaseous phase cryogenic fluid.

[0091] During export of LNG, the present invention uses some of the cold produced by re-gasification of the LNG to re-liquefy boil-off gas. The boil-off gas is compressed with a compressor; and cooled in counter-flow heat exchange with the refrigerant in the closed-loop refrigeration cycle, whereby its condenses into liquid phase.

[0092] During times of zero export of LNG (i.e. when no LNG is exported on the network), the present invention uses the cold stored in the cryogenic fluid to re-liquefy boil-off gas. Thus, the boil-off gas is compressed using a compressor; and cooled in heat exchange with the cryogenic fluid such that it becomes liquid.

[0093] The warmed cryogenic fluid is thus vaporised, super-heated; and expanded isentropically through one or multiple turbo-expansion stages, thus producing work.

[0094] During times of low export of LNG, the present invention may use both the cold from the re-gasification of LNG and the cold stored in the cryogenic fluid to re-liquefy boil-off gas.

[0095] The system is able to operate flexibly, at different operating points, by altering the flow of boil-off gas (e.g. by changing the flow rate and/or by redirecting the boil-off gas as described below) and by adjusting the duty of the nitrogen and boil-off gas compressors accordingly.

[0096] A cryogenic store (e.g. storage tank) is provided for storing the cryogenic fluid, allowing the flow of cryogenic fluid in and the flow of cryogenic fluid out to be controlled independently. Thus, the heat transfer rate between the cryogenic fluid and the LNG, and the heat transfer rate between the boil-off gas and the cryogenic fluid from the cryogenic storage tank, may be independently and dynamically controlled by varying the flow rate of the cryogenic fluid into and the flow rate of the cryogenic fluid out of the cryogenic storage tank respectively. The re-gasification of LNG and the re-liquefaction of boil-off gas may therefore occur independently at different times and at different rates.

[0097] As a skilled person will recognise, the larger the volume of the cryogenic storage tank, the longer the period that boil-off gas may be re-liquefied during times of low, or zero, LNG send-out.

[0098] The flow rates may be controlled in response to both current, real time operational parameters and future predicted operational parameters in order to optimise the management of the LNG stock in the LNG tank. Operational parameters include, for example, one or more of demand for LNG, availability of LNG or cryogenic fluid, and rate of boil-off

[0099] In one example, the flow rate of liquid cryogenic fluid out of the cryogenic storage tank may be controlled as a function of the measured flow of boil-off gas. Alternatively, if the period of low, or zero, LNG sendout is predicted to be short, it may be preferential to economise the stock of liquid cryogenic fluid in the cryogenic storage tank and allow boil-off gas to accumulate within the pressure limits of the LNG tank.

[0100] In another example, the flow-rate of gaseous cryogenic fluid may be controlled as a function of the LNG sendout rate. Alternatively, it may be reduced as the cryogenic storage tank approaches full capacity.

[0101] In one embodiment, during LNG send-out, boil-off gas may be mixed in its gaseous phase with the gasified liquid natural gas rather than being re-liquefied.

[0102] Turning to the system diagram shown in Fig.1, the cold boil-off gas, which comes from an LNG tank or a chamber, vessel, header or anywhere where boil-off gas is collected, is withdrawn via conduit 1 by compressor 3. Boil-off gas is compressed into conduit 2 from the tank storage pressure, which normally is just above ambient pressure, to between 1 and 10 bar, but more typically 3 to 6 bar. At times of high LNG send-out rate no fraction of boil-off gas is diverted into conduit 42 but it is all conveyed through conduit 4 and liquefied and sub-cooled In heat exchanger 5. Boil-off gas, which is now in its liquid form, thus can be used as LNG, is then expanded through an expansion device 7, and conveyed by pump 9 to an LNG tank 11 via conduit 10. Purely for completeness, it will be appreciated that the method of independent claim 1 is not performed if no heat is transferred from the stream of boil-off gas to the stream of cryogenic fluid from the fluid store.

[0103] Nitrogen, in gaseous form, available at a pressure between 1 and 16 bar, but more typically 6 to 9 bar, is withdrawn via conduit 12 and passed through heat exchanger 13 where it is cooled to near LNG storage temperature. Nitrogen is then compressed by a single or multistage compressor 15 to a pressure between 50 and 70 bar, but more typically 54 to 60 bar. Nitrogen, which is now above its supercritical pressure, is cooled in heat exchanger 5 to between -155°C and -185°C, but more typically -165°C and -175°C. Leaving the heat exchanger the nitrogen passes through conduit 21 and then expands through the expansion device 22. The liquid fraction obtained from the isenthalpic expansion, which in this embodiment is 100%, passes through conduit 23 to reach the liquid nitrogen storage tank 24.

[0104] Cooling to heat exchanger 5 is supplied by the refrigeration cycle shown between heat exchangers 5 and 29, where a refrigerant gas, typically nitrogen, is compressed by compressor 37 to between 4 bar and 16 bar, but more typically 7 bar to 10 bar, fed to heat exchanger 29, wherein it is cooled by heat exchange with LNG to between -161°C and - 140°C, but more typically -156°C. The cold refrigerant passes through conduit 39 to reach the inlet of the expansion device 40, where the refrigerant is expanded to between 1 bar and 7 bar, but more typically 2 to 4 bar. The refrigerant passes through conduit 41 and is fed to heat exchanger 5 at a temperature between -190°C and -170°C, more typically - 185°C.

[0105] Cooling to heat exchangers 29 and 13 is supplied by the LNG which is withdrawn from the LNG tank 11 by the LNG pump 26, pumped to a pressure between 60bar and 150 bar, more typically 80 bar and 120 bar. The high pressure LNG in conduit 27 is then split in two streams. A proportion of the LNG flow is directed to heat exchanger 29 via conduit 28 and the rest is sent to heat exchanger 13 via conduit 32. Conduit 30 and 33 are merged together to form conduit 34 and convey the LNG, which is now in gaseous form, to the natural gas distribution network.

[0106] Similarly to any other commodity, LNG is subject to a volatile demand which means that the send-out rate can vary between 0% and 100% of the maximum capacity of the LNG re-gasification terminal. When the send-out rate is above a certain threshold there is enough cold to liquefy the boil-off gas stream and the nitrogen stream. However when the send-out rate drops below this threshold it is enough to turn down the nitrogen compressor 15 to adjust the system to the new operating conditions. However the preferred system can easily adjust to any level of send-out rate by completely stopping compressor 15 and, should the LNG send-out rate drop even further, diverting some of the compressed boil-off gas to conduit 42. The boil-off gas is then conveyed to heat exchanger 43, wherein it is cooled, liquefied and subcooled by heat exchange with liquid nitrogen. Boil-off gas, which is now in its liquid form, is then expanded through an expansion device 45, and conveyed by pump 47 to an LNG tank 11 via conduit 48.

[0107] The liquid nitrogen flow rate which passes through heat exchanger 43 is throttled by control valve 50. The nitrogen emerges from heat exchanger 43 in conduit 52 in its gaseous form. The nitrogen is then superheated in heat exchanger 53 to any temperature up to 500°C and expanded through a turbine 55 to recover the energy. Depending by the pressure and type of machine employed the expansion of the nitrogen stream can be done in a single stage, two stages, as shown in Fig.1, or several stages with intermediate heat exchangers for superheating the nitrogen.

[0108] Control of the system is achieved using any conventional controller which operates to vary the duty of gaseous cryogenic fluid compressor 15 to control the flow rate of the stream of gaseous cryogenic fluid; open and close valve 50 to control the flow rate of the stream of liquefied cryogenic fluid from tank 24; and optionally vary the duty of gaseous boil-off gas compressor 3 to control the flow rate of the stream of gaseous boil-off gas. However, other means for controlling the flow rates of these streams are possible and within the capabilities of a skilled person to implement depending on particular circumstances.

[0109] A system diagram of a second embodiment of the invention is shown in Fig.2. The second embodiment is identical to the first in every way, except that the cryogenic fluid is air rather than nitrogen. Thus, conduit 12 no longer coveys gaseous nitrogen but ambient air which has undergone a cleaning, scrubbing and drying process. Ambient air is withdrawn through conduit 61, it undergoes a first stage of cleaning as it passes through the air filter 62, compressed by compressor 64, sent to the air filtration unit 66, where moisture, carbon dioxide and hydrocarbons are removed, before emerging as clean and dry air in conduit 12.

[0110] A system diagram of a third embodiment of the invention is shown in Fig.3. The third embodiment is identical to the first in every way, except that the liquid fraction obtained from the isenthalpic expansion of the nitrogen is not 100%, resulting in a vapour or gas phase of nitrogen existing immediately upstream of the nitrogen tank 24. Thus, in this embodiment, a separator 17 is added between the tank 24 and the expansion device 22. The liquid and the vapour fraction obtained from the isenthalpic expansion passes through conduit 23 to reach the separator 17, wherein the liquid fraction is conveyed via conduit 18 to the nitrogen storage tank 24 and the vapour fraction is conveyed via conduit 19 to heat exchanger 5. The nitrogen is warmed by heat exchange with incoming warm nitrogen and boil-off gas in heat exchanger 5 and then conveyed via conduit 20 back to the suction side of compressor 15 where it joins the incoming nitrogen in conduit 12.

[0111] A system diagram of a fourth embodiment of the invention is shown in Fig.4. The fourth embodiment is identical to the first in every way, except that a pump 35 is installed downstream of the control valve to raise the pressure of the liquefied nitrogen from the nitrogen tank to between 100 bar and 200 bar, but more typically 120 bar and 150 bar. The nitrogen emerges from heat exchanger 43 at high pressure and enters conduit 52 in its gaseous form. The nitrogen is then superheated in heat exchanger 53 to any temperature up to 500°C and expanded through a turbine 55 to recover the energy. Depending on the pressure and type of machine employed the expansion of the nitrogen stream can be done in a single stage, two stages, as shown in Fig.4, or several stages with intermediate heat exchangers for superheating the nitrogen. In this embodiment the expansion turbines would be able to generate more power per unit mass of nitrogen compared to the first embodiment of this invention but a higher flow rate of nitrogen would be required to liquefy the same boil-off gas flow rate.

[0112] A system diagram of a fifth embodiment of the invention is shown in Fig.5. The fifth embodiment is identical to the first in every way, except that heat exchanger 5 and heat exchanger 43 from previous embodiments are replaced with a single heat exchanger 70. In this embodiment the system no longer needs a separate heat exchanger to liquefy the boil-off gas when using liquid nitrogen.

Claims

1. A method for liquefying boil-off gas, comprising:

storing a liquefied hydrocarbon gas in a liquefied hydrocarbon gas store (11);

processing a stream of gaseous cryogenic fluid and a stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store (11), such that:

a) the stream of liquefied hydrocarbon gas undergoes a phase change from a liquefied hydrocarbon gas to a gaseous hydrocarbon gas; and

b) the stream of gaseous cryogenic fluid undergoes a phase change from a gaseous cryogenic fluid to a liquefied cryogenic fluid;

wherein the step of processing comprises transferring heat from the stream of gaseous cryogenic fluid to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store (11);

storing the liquefied cryogenic fluid in a liquefied cryogenic fluid store (24);

processing a stream of gaseous boil-off gas and a stream of liquefied cryogenic fluid from the liquefied cryogenic fluid store (24) such that:

a) the stream of liquefied cryogenic fluid undergoes a phase change from a liquefied cryogenic fluid to a gaseous cryogenic fluid; and

b) the stream of gaseous boil-off gas undergoes a phase change from a gaseous boil-off gas to a liquefied boil-off gas;

wherein the step of processing comprises transferring heat from the stream of gaseous boil-off gas to the stream of liquefied cryogenic fluid from the liquefied cryogenic fluid store (24);

storing the liquefied boil-off gas in the liquefied hydrocarbon gas store (11);

controlling the flow rate of the stream of gaseous cryogenic fluid based at least in part on the flow rate of the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store (11); and

independently controlling the flow rate of the stream of liquefied cryogenic fluid from the liquefied cryogenic fluid store (24) based at least in part on the flow rate of the stream of gaseous boil-off gas; the method characterised in that

the step of transferring heat from the stream of gaseous cryogenic fluid to the stream of liquefied hydrocarbon gas from the hydrocarbon gas store (11) further comprises:

transferring heat from the stream of gaseous cryogenic fluid to a heat transfer fluid in a closed-loop refrigeration circuit (37, 39, 40, 41) and cooling the gaseous cryogenic fluid to a temperature below the saturation temperature of the liquefied hydrocarbon gas; and

transferring heat from the heat transfer fluid in the closed-loop refrigeration circuit to the stream of liquefied hydrocarbon gas.

2. A system for liquefying boil-off gas, comprising:

a first store (11) for storing liquefied hydrocarbon gas;

a first arrangement of conduits (30, 33, 34) coupled to the first store (11) and to a hydrocarbon gas network for delivering hydrocarbon gas to a recipient;

a second arrangement of conduits (1, 2) coupled to a source of boil-off gas and to the first store (11) for delivering liquefied boil-off gas to the first store (11);

a second store (24) for storing a liquefied cryogenic fluid:

a third arrangement of conduits (12, 21) coupled to a source of gaseous cryogenic fluid and the second store (24) for delivering liquefied cryogenic fluid to the second store (24);

a fourth arrangement of conduits (52) coupled to the second store (24) for delivering cryogenic fluid from the second store (24); wherein:

the first (30, 33, 34) and third (12, 21) arrangements of conduits are arranged such that heat is transferred from a stream of gaseous cryogenic fluid passing through the third arrangement of conduits (12, 21) to a stream of liquefied hydrocarbon gas passing through the first arrangement of conduits (30, 33, 34);

the second (1, 2) and fourth (52) arrangements of conduits are arranged such that heat is transferred from a stream of gaseous boil-off gas passing through the second arrangement of conduits (1, 2) to a stream of liquefied cryogenic fluid passing through the fourth arrangement of conduits (52); and

a controller configured to:

a) control the flow rate of the stream of gaseous cryogenic fluid passing through the third arrangement of conduits (12, 21) based at least in part on the flow rate of the stream of liquefied hydrocarbon gas passing through the first arrangement of conduits (30, 33, 34); and

b) independently control the flow rate of the stream of liquefied cryogenic fluid passing through the fourth arrangement of conduits (52) based at least in part on the flow rate of the stream of gaseous boil-off gas passing through the second arrangement of conduits (1, 2);

and characterised in that the system further comprises a fifth arrangement of conduits (39, 41) being arranged as a closed-loop refrigeration circuit (37, 39, 40. 41) comprising a heat transfer fluid passing through the fifth arrangement of conduits, wherein:
the first (30, 33, 34) and third (12, 21) arrangements of conduits are arranged such that heat is transferred between the first (30, 33, 34) and third (12, 21) arrangements of conduits via the closed-loop refrigeration circuit (37, 39, 40, 41). wherein:

the fifth (39, 41) and third (12, 21) arrangements of conduits are arranged such that heat is transferred from the stream of gaseous cryogenic fluid passing through the third arrangement of conduits (12, 21) to the heat transfer fluid passing through the fifth arrangement of conduits (39, 41); and

the fifth (39, 41) and first (30, 33, 34) arrangements of conduits are arranged such that heat is transferred from the heat transfer fluid passing through the fifth arrangement of conduits (39, 41) to the stream of liquefied hydrocarbon gas passing through the first (30, 33, 34) arrangement of conduits.

3. The method of claim 1, further comprising the step of processing the stream of gaseous boil-off gas and the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store (11) such that:

a) the stream of liquefied hydrocarbon gas undergoes a phase change from a liquefied hydrocarbon gas to a gaseous hydrocarbon gas; and

b) the stream of gaseous boil-off gas undergoes a phase change from a gaseous boil-off gas to a liquefied boil-off gas;

wherein the step of processing comprises transferring heat from the stream of gaseous boil-off gas to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store (11); or the system of claim 2, wherein the first (30, 33, 34) and second (1, 2) arrangements of conduits are arranged such that heat is transferred from the stream of gaseous boil-off gas passing through the second arrangement of conduits (1, 2) to the stream of liquefied hydrocarbon gas passing through the first arrangement of conduits (30, 33, 34).

4. The method of claim 3, wherein the steps of:

a) transferring heat from the stream of gaseous cryogenic fluid to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store (11); and

b) transferring heat from the stream of gaseous boil-off gas to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store (11);

are concurrent.

5. The method of any one of claims 1, 3 or 4, wherein the step of processing the stream of gaseous cryogenic fluid and the stream of liquefied hydrocarbon gas further comprises the steps of:

expanding the stream of gaseous cryogenic fluid after heat transfer, and

compressing the stream of gaseous cryogenic fluid prior to heat transfer;

wherein the step of compressing the stream of gaseous cryogenic fluid prior to heat transfer comprises compressing the stream to a supercritical pressure.

6. The method of claim 5, further comprising the steps of passing the stream of liquefied hydrocarbon gas through first (32) and second (28) branches;
wherein the step of transferring heat from the stream of gaseous cryogenic fluid to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store (11) further comprises:

transferring heat to a stream of liquefied hydrocarbon gas in the first branch (32) from the stream of gaseous cryogenic fluid prior to compression; and

transferring heat to a stream of liquefied hydrocarbon gas in the second branch (28) from the stream of gaseous cryogenic fluid after compression via the closed-loop refrigeration circuit (37, 39, 40, 41).

7. The method of any one of claims 1 or 3 to 6, further comprising the step of delivering the stream of gaseous hydrocarbon gas to a recipient,
wherein the recipient is one or more of: a hydrocarbon pipe network; a power station; and a consumer of gaseous hydrocarbon gas.

8. The method of any one of claims 1 or 3 to 7, further comprising the step of collecting the stream of gaseous boil-off gas from the liquefied hydrocarbon gas store (11);
wherein the step of collecting the stream of gaseous boil-off gas comprises collecting the boil-off gas from a store, or collection point coupled to the liquefied hydrocarbon gas store (11).

9. The system of claim 2 or claim 3, wherein the third arrangement of conduits (12, 21) comprises a compressor (15) for compressing the stream of gaseous cryogenic fluid to a supercritical pressure, and an expander (22) for expanding the stream of cryogenic fluid at supercritical pressure to condense and form a cryogenic liquid after heat exchange with the heat transfer fluid passing through the fifth arrangement of conduits (39, 41); and wherein the first arrangement of conduits (30, 33, 34) comprises a first branch (32) and a second branch (28);
the first branch (32) being arranged such that heat is transferred to a stream of liquefied hydrocarbon gas passing through the first branch (32) from the stream of gaseous cryogenic fluid passing through the third arrangement of conduits (12, 21) at a first heat exchange region (13) upstream of the compressor (15); and
the second branch (30) being arranged such that heat is transferred to a stream of liquefied hydrocarbon gas passing through the second branch from the stream of gaseous cryogenic fluid passing through the third arrangement of conduits (12, 21) at a second heat exchange region (5, 29) downstream of the compressor (15) via the closed-loop refrigeration circuit (37, 39, 40, 41).

10. The system of claim 9, wherein the first (32) and second (28) branches bifurcate from a single conduit (27) upstream of the first and second heat exchange regions, and recombine to a single conduit (34) downstream of the first (13) and second (5, 29) heat exchange regions.

11. The system of any one of claims 2, 3, 9, or 10, wherein the source of boil-off gas is the first store (11), or a store, conduit, or collection point coupled to the first store (11).

12. The method of claim 3, or any method claim dependent thereon, wherein the step of transferring heat from the stream of gaseous boil-off gas to the stream of liquefied hydrocarbon gas from the liquefied hydrocarbon gas store (11) further comprises:

transferring heat from the stream of gaseous boil-off gas to the heat transfer fluid in the closed-loop refrigeration circuit; and

transferring heat from the heat transfer fluid in the closed-loop refrigeration circuit to the stream of liquefied hydrocarbon gas; or the system of claim 3, or any system claim dependent thereon, wherein the first (30, 33, 34) and second (1, 2) arrangements of conduits are arranged such that heat is transferred between the first (30, 33, 34) and second (1, 2) arrangements of conduits via the closed-loop refrigeration circuit, wherein:
the fifth (39, 41) and second (1, 2) arrangements of conduits are arranged such that heat is transferred from the stream of gaseous boil-off gas passing through the second arrangement of conduits (1, 2) to the heat transfer fluid passing through the fifth arrangement of conduits (39, 41).

13. The system of claim 9, wherein the second branch is arranged such that heat is transferred from the heat transfer fluid passing through the fifth arrangement of conduits (39, 41) to the stream of liquefied hydrocarbon gas passing through the second branch.

14. The method of any one of claims 1, 3 to 8, or 12, further comprising processing a stream of ambient air to form the stream of gaseous cryogenic fluid, wherein the step of processing the stream of ambient air comprises one or both of the steps of:

filtering the stream of ambient air to remove moisture, carbon dioxide and/or hydrocarbons; and

compressing the stream of ambient air; or the system of any one of claims 2, 3, 9 to 11, 12, or 13, wherein the stream of gaseous cryogenic fluid is air, and wherein the third arrangement of conduits (12, 21) further comprises one or both of:

a filtration system for removing moisture, carbon dioxide and/or hydrocarbons from a stream of ambient air; and

a compressor for compressing a stream of ambient air.

15. The method of any one of claims 1, 3 to 6, 12 or 14, further comprising passing the stream of liquefied cryogenic fluid through a separator prior to it entering the liquefied cryogenic fluid tank to separate any residual vapour phase from the stream of liquefied cryogenic fluid, and returning the residual vapour phase to the stream of gaseous cryogenic fluid; or the system of any one of claims 2, 3, 9 to 11, or 12 to 14, wherein the third arrangement of conduits (12. 21) further comprises a separator upstream of the second store (24) for extracting any residual vapour phase from the stream of liquefied cryogenic fluid passing through the third arrangement of conduits (12, 21) prior to entering the second store (24), and a return conduit arranged to direct the residual vapour phase extracted from the stream of liquefied cryogenic fluid to the stream of gaseous cryogenic fluid passing through the third arrangement of conduits (12, 21).

16. The method of any one of claims 1, 3 to 8, 12, 14 or 15, further comprising pumping the stream of liquefied cryogenic fluid from the liquefied cryogenic fluid store (24) to increase its pressure prior to the step of transferring heat from the stream of gaseous boil-off gas to the stream of liquefied cryogenic fluid from the liquefied cryogenic fluid store (24); or the system of any one of claims 2, 3, 9 to 11, or 12 to 15, wherein the second (1, 2) and fourth (52) arrangements of conduits are arranged such that heat is transferred between the second (1, 2) and fourth (52) arrangements of conduits at a third heat exchange region (43), and wherein the fourth arrangement of conduits (52) further comprises a pump upstream of the third heat exchange region (43) for pumping the stream of liquefied cryogenic fluid passing through the fourth arrangement of conduits (52) prior to it passing through the third heat exchange region (43).

17. The method of any one of claims 1, 3 to 8. 12 or 14 to 16, wherein the step of transferring heat from the stream of gaseous boil-off gas to the stream of liquefied cryogenic fluid from the liquefied cryogenic fluid store (24) such that the stream of liquefied cryogenic fluid undergoes a phase change from a liquefied cryogenic fluid to a gaseous cryogenic fluid results in a second stream of gaseous cryogenic fluid, the method further comprising the steps of expanding the second stream of gaseous cryogenic fluid to extract work from the stream; super-heating the second stream of gaseous cryogenic fluid prior to one or more stages of expansion; and converting the work extracted from the second stream into electricity; wherein the step of expanding the second stream of gaseous cryogenic fluid to extract work from the second stream is performed in a single-stage expansion device, a two-stage expansion device, or a multi-stage expansion device; or the system of claim 16, wherein the third heat exchange region (43) is configured such that heat is transferred from the stream of gaseous boil-off gas passing through the second arrangement of conduits (1, 2) to the stream of liquefied cryogenic fluid passing through the fourth arrangement of conduits (52) to produce a second stream of gaseous cryogenic fluid, and wherein the fourth arrangement of conduits (52) further comprises an expansion device for expanding the second stream of gaseous cryogenic fluid and extracting work from the second stream of cryogenic fluid;
wherein the expansion device is a single-stage expansion device, a two-stage expansion device, or a multi-stage expansion device;
wherein the fourth arrangement of conduits (52) is coupled to one or more super-heaters, and wherein each super-heater is either upstream of the first stage of the expansion device or between stages of the expansion device.

18. The system of any one of claims 2, 3, 9, 10, or 11, further comprising one or more heat exchangers (5, 13, 29, 43) wherein the first (30, 33, 34), second (1, 2), third (12, 21) and fourth (52) arrangements of conduits are arranged such that heat is transferred between the first (30, 33, 34) and third (12, 21) arrangements of conduits, between the second (1, 2) and fourth (52) arrangements of conduits by the one or more heat exchangers (5, 13, 29, 43).

19. The system of claim 18, when dependent on claim 3 or any claim dependent thereon, wherein the first (30, 33, 34), second (1, 2), third (12, 21) and fourth (52) arrangements of conduits are arranged such that heat is transferred between the first (30, 33, 34) and second (1, 2) arrangements of conduits by the one or more heat exchangers (5, 13, 29, 43).

20. The system of claim 2 or the method of claim 1, or any claim dependent thereon, wherein the closed-loop refrigeration circuit operates using one of a single-phase Brayton cycle and a dual-phase Rankine cycle.

21. The system of claim 2 or the method of claim 1, or any claim dependent thereon, wherein the heat transfer fluid is one of nitrogen or propane.

22. The system of any one of claims 2, 3, or 9 to 21 or method of any one of claims 1, 3 to 8, 12, 14 to 17, 20, or 21 wherein the cryogenic fluid is one of nitrogen or air, preferably ambient air.

23. The system of any one of claims 2 to 3 or 9 to 22 or method of any one of claims 1, 3 to 8, 12, 14 to 17, 20, 21 or 22 wherein the liquefied hydrocarbon gas is Liquefied Natural Gas (LNG).

Ansprüche

1. Verfahren zum Verflüssigen von Boil-off-Gas, umfassend:

Speichern eines verflüssigten Kohlenwasserstoffgases in einem Speicher (11) für verflüssigtes Kohlenwasserstoffgas;

Aufbereiten eines Stroms aus gasförmigem tiefkaltem Fluid und eines Stroms aus verflüssigtem Kohlenwasserstoffgas aus dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas derart, dass:

a) der Strom aus verflüssigtem Kohlenwasserstoffgas seinen Aggregatzustand von einem verflüssigten Kohlenwasserstoffgas in ein gasförmiges Kohlenwasserstoffgas ändert; und

b) der Strom aus gasförmigem tiefkaltem Fluid seinen Aggregatzustand von einem gasförmigen tiefkalten Fluid in ein verflüssigtes tiefkaltes Fluid ändert;

wobei der Schritt des Aufbereitens ein Übertragen von Wärme von dem Strom aus gasförmigem tiefkaltem Fluid auf den Strom aus verflüssigtem Kohlenwasserstoffgas aus dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas umfasst;

Speichern des verflüssigten tiefkalten Fluids in einem Speicher (24) für verflüssigtes tiefkaltes Fluid;

Aufbereiten eines Stroms aus gasförmigem Boil-off-Gas und eines Stroms aus verflüssigtem tiefkaltem Fluid aus dem Speicher (24) für verflüssigtes tiefkaltes Fluid derart, dass:

a) der Strom aus verflüssigtem tiefkaltem Fluid seinen Aggregatzustand von einem verflüssigten tiefkalten Fluid in ein gasförmiges tiefkaltes Fluid ändert; und

b) der Strom aus gasförmigem Boil-off-Gas seinen Aggregatzustand von einem gasförmigen Boil-off-Gas in ein verflüssigtes Boil-off-Gas ändert;

wobei der Schritt des Aufbereitens ein Übertragen von Wärme von dem Strom aus gasförmigem Boil-off-Gas auf den Strom aus verflüssigtem tiefkaltem Fluid aus dem Speicher (24) für verflüssigtes tiefkaltes Fluid umfasst;

Speichern des verflüssigten Boil-off-Gases in dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas;

Regeln des Durchflusses des Stroms aus gasförmigem tiefkaltem Fluid zumindest teilweise auf Grundlage des Durchflusses des Stroms aus verflüssigtem Kohlenwasserstoffgas aus dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas; und

unabhängig davon Regeln des Durchflusses des Stroms aus verflüssigtem tiefkaltem Fluid aus dem Speicher (24) für verflüssigtes tiefkaltes Fluid zumindest teilweise auf Grundlage des Durchflusses des Stroms aus gasförmigem Boil-off-Gas; wobei das Verfahren dadurch gekennzeichnet ist, dass

der Schritt des Übertragens von Wärme von dem Strom aus gasförmigem tiefkaltem Fluid auf den Strom aus verflüssigtem Kohlenwasserstoffgas aus dem Speicher (11) für Kohlenwasserstoffgas ferner umfasst:

Übertragen von Wärme von dem Strom aus gasförmigem tiefkaltem Fluid auf ein Wärmeträgerfluid in einem geschlossenen Kühlkreislauf (37, 39, 40, 41) und Abkühlen des gasförmigen tiefkalten Fluids auf eine Temperatur unter der Sättigungstemperatur des verflüssigten Kohlenwasserstoffgases; und

Übertragen von Wärme von dem Wärmeträgerfluid in dem geschlossenen Kühlkreislauf auf den Strom aus verflüssigtem Kohlenwasserstoffgas.

2. System zum Verflüssigen von Boil-off-Gas, umfassend:

einen ersten Speicher (11) zum Speichern von verflüssigtem Kohlenwasserstoffgas;

eine erste Anordnung aus Leitungen (30, 33, 34), die zum Befördern von Kohlenwasserstoffgas zu einer Abnahmestelle mit dem ersten Speicher (11) und mit einem Kohlenwasserstoffgasnetz verbunden ist;

eine zweite Anordnung aus Leitungen (1, 2), die zum Befördern von verflüssigtem Boil-off-Gas zum ersten Speicher (11) mit einer Quelle für Boil-off-Gas und mit dem ersten Speicher (11) verbunden ist;

einen zweiten Speicher (24) zum Speichern eines verflüssigten tiefkalten Fluids;

eine dritte Anordnung aus Leitungen (12, 21), die zum Befördern von verflüssigtem tiefkaltem Fluid zum zweiten Speicher (24) mit einer Quelle für gasförmiges tiefkaltes Fluid und mit dem zweiten Speicher (24) verbunden ist;

eine vierte Anordnung aus Leitungen (52), die zum Befördern von tiefkaltem Fluid aus dem zweiten Speicher (24) heraus mit dem zweiten Speicher (24) verbunden ist; wobei:

die erste (30, 33, 34) und dritte (12, 21) Anordnung aus Leitungen derart angeordnet sind, dass Wärme von einem Strom aus gasförmigem tiefkaltem Fluid, der durch die dritte Anordnung aus Leitungen (12, 21) strömt, auf einen Strom aus verflüssigtem Kohlenwasserstoffgas übertragen wird, der durch die erste Anordnung aus Leitungen (30, 33, 34) strömt;
die zweite (1, 2) und vierte (52) Anordnung aus Leitungen derart angeordnet sind, dass Wärme von einem Strom aus gasförmigem Boil-off-Gas, der durch die zweite Anordnung aus Leitungen (1, 2) strömt, auf einen Strom aus verflüssigtem tiefkaltem Fluid übertragen wird, der durch die vierte Anordnung aus Leitungen (52) strömt; und

einen Regler, der derart eingerichtet ist, dass er:

a) den Durchfluss des Stroms aus gasförmigem tiefkaltem Fluid, der durch die dritte Anordnung aus Leitungen (12, 21) strömt, zumindest teilweise auf Grundlage des Durchflusses des Stroms aus verflüssigtem Kohlenwasserstoffgas, der durch die erste Anordnung aus Leitungen (30, 33, 34) strömt, regelt; und

b) unabhängig davon den Durchfluss des Stroms aus verflüssigtem tiefkaltem Fluid, der durch die vierte Anordnung aus Leitungen (52) strömt, zumindest teilweise auf Grundlage des Durchflusses des Stroms aus gasförmigem Boil-off-Gas, der durch die zweite Anordnung aus Leitungen (1, 2) strömt, regelt;

und dadurch gekennzeichnet, dass das System ferner eine fünfte Anordnung aus Leitungen (39, 41) umfasst, die als geschlossener Kühlkreislauf (37, 39, 40, 41) angeordnet sind, der ein Wärmeträgerfluid umfasst, das durch die fünfte Anordnung aus Leitungen strömt, wobei:

die erste (30, 33, 34) und dritte (12, 21) Anordnung aus Leitungen derart angeordnet sind, dass Wärme zwischen der ersten (30, 33, 34) und dritten (12, 21) Anordnung aus Leitungen über den geschlossenen Kühlkreislauf (37, 39, 40, 41) übertragen wird, wobei:

die fünfte (39, 41) und dritte (12, 21) Anordnung aus Leitungen derart angeordnet sind, dass Wärme von dem Strom aus gasförmigem tiefkalten Fluid, der durch die dritte Anordnung aus Leitungen (12, 21) strömt, auf das Wärmeträgerfluid übertragen wird, das durch die fünfte Anordnung aus Leitungen (39, 41) strömt; und

die fünfte (39, 41) und erste (30, 33, 34) Anordnung aus Leitungen derart angeordnet sind, dass Wärme von dem Wärmeträgerfluid, das durch die fünfte Anordnung aus Leitungen (39, 41) strömt, auf den Strom aus verflüssigtem Kohlenwasserstoffgas übertragen wird, der durch die erste (30, 33, 34) Anordnung aus Leitungen strömt.

3. Verfahren nach Anspruch 1, ferner umfassend den Schritt des derartigen Aufbereitens des Stroms aus gasförmigem Boil-off-Gas und des Stroms aus verflüssigtem Kohlenwasserstoffgas aus dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas, dass:

a) der Strom aus verflüssigtem Kohlenwasserstoffgas seinen Aggregatzustand von einem verflüssigten Kohlenwasserstoffgas in ein gasförmiges Kohlenwasserstoffgas ändert; und

b) der Strom aus gasförmigem Boil-off-Gas seinen Aggregatzustand von einem gasförmigen Boil-off-Gas in ein verflüssigtes Boil-off-Gas ändert;

wobei der Schritt des Aufbereitens ein Übertragen von Wärme von dem Strom aus gasförmigem Boil-off-Gas auf den Strom aus verflüssigtem Kohlenwasserstoffgas aus dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas umfasst; oder System nach Anspruch 2, wobei die erste (30, 33, 34) und zweite (1, 2) Anordnung aus Leitungen derart angeordnet sind, dass Wärme von den Strom aus gasförmigem Boil-off-Gas, der durch die zweite Anordnung aus Leitungen (1, 2) strömt, auf den Strom aus verflüssigtem Kohlenwasserstoffgas, der durch die erste Anordnung aus Leitungen (30, 33, 34) strömt, übertragen wird.

4. Verfahren nach Anspruch 3, wobei die Schritte:

a) des Übertragens von Wärme von dem Strom aus gasförmigem tiefkaltem Fluid auf den Strom aus verflüssigtem Kohlenwasserstoffgas aus dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas; und

b) des Übertragens von Wärme von dem Strom aus gasförmigem Boil-off-Gas auf den Strom aus verflüssigtem Kohlenwasserstoffgas aus dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas gleichzeitig ablaufen.

5. Verfahren nach einem der Ansprüche 1, 3 oder 4, wobei der Schritt des Aufbereitens des Stroms aus gasförmigem tiefkaltem Fluid und des Stroms aus verflüssigtem Kohlenwasserstoffgas ferner folgende Schritte umfasst:

Entspannen des Stroms aus gasförmigem tiefkaltem Fluid nach der Wärmeübertragung und

Verdichten des Stroms aus gasförmigem tiefkaltem Fluid vor der Wärmeübertragung,

wobei der Schritt des Verdichtens des Stroms aus gasförmigem tiefkaltem Fluid vor der Wärmeübertragung ein Verdichten des Stroms auf einen überkritischen Druck umfasst.

6. Verfahren nach Anspruch 5, ferner umfassend die Schritte des Leitens des Stroms aus verflüssigtem Kohlenwasserstoffgas durch eine erste (32) und zweite (28) Abzweigung;
wobei der Schritt des Übertragens von Wärme von dem Strom aus gasförmigem tiefkaltem Fluid auf den Strom aus verflüssigtem Kohlenwasserstoffgas aus dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas ferner umfasst:

Übertragen von Wärme auf einen Strom aus verflüssigtem Kohlenwasserstoffgas in der ersten Abzweigung (32) von dem Strom aus gasförmigem tiefkaltem Fluid vor dem Verdichten; und

Übertragen von Wärme auf einen Strom aus verflüssigtem Kohlenwasserstoffgas in der zweiten Abzweigung (28) von dem Strom aus gasförmigem tiefkaltem Fluid nach dem Verdichten über den geschlossenen Kühlkreislauf (37, 39, 40, 41).

7. Verfahren nach einem der Ansprüche 1 oder 3 bis 6, ferner umfassend den Schritt des Beförderns des Stroms aus gasförmigem Kohlenwasserstoffgas zu einer Abnahmestelle;
wobei die Abnahmestelle ein Kohlenwasserstoffrohrleitungsnetz und/oder ein Kraftwerk und/oder ein Verbraucher von gasförmigem Kohlenwasserstoffgas ist.

8. Verfahren nach einem der Ansprüche 1 oder 3 bis 7, ferner umfassend den Schritt des Sammelns des Stroms aus gasförmigem Boil-off-Gas aus dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas;
wobei der Schritt des Sammelns des Stroms aus gasförmigem Boil-off-Gas ein Sammeln des Boil-off-Gases aus einem Speicher oder von einem Sammelpunkt umfasst, der mit dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas verbunden ist.

9. System nach Anspruch 2 oder Anspruch 3, wobei die dritte Anordnung aus Leitungen (12, 21) einen Verdichter (15) zum Verdichten des Stroms aus gasförmigem tiefkaltem Fluid auf einen überkritischen Druck umfasst, sowie eine Entspannungsmaschine (22) zum Entspannen des Stroms aus tiefkaltem Fluid bei dem überkritischen Druck, damit er nach einem Wärmeaustausch mit dem Wärmeträgerfluid, das durch die fünfte Anordnung aus Leitungen (39, 41) strömt, kondensiert und eine tiefkalte Flüssigkeit bildet; und wobei die erste Anordnung aus Leitungen (30, 33, 34) eine erste Abzweigung (32) und eine zweite Abzweigung (28) umfasst;
wobei die erste Abzweigung (32) derart angeordnet ist, dass auf einen Strom aus verflüssigtem Kohlenwasserstoffgas, der durch die erste Abzweigung (32) strömt, von dem Strom aus gasförmigem tiefkaltem Fluid, der durch die dritte Anordnung aus Leitungen (12, 21) strömt, in einem ersten Wärmeaustauschbereich (13) in Strömungsrichtung vor dem Verdichter (15) Wärme übertragen wird; und
wobei die zweite Abzweigung (30) derart angeordnet ist, dass auf einen Strom aus verflüssigtem Kohlenwasserstoffgas, der durch die zweite Abzweigung strömt, von dem Strom aus gasförmigem tiefkaltem Fluid, der durch die dritte Anordnung aus Leitungen (12, 21) strömt, in einem zweiten Wärmeaustauschbereich (5, 29) in Strömungsrichtung hinter dem Verdichter (15) über den geschlossenen Kühlkreislauf (37, 39, 40, 41) Wärme übertragen wird.

10. System nach Anspruch 9, wobei sich die erste (32) und zweite (28) Abzweigung von einer einzigen Leitung (27) in Strömungsrichtung vor dem ersten und zweiten Wärmeaustauschbereich aufzweigen und sich in Strömungsrichtung hinter dem ersten (13) und zweiten (5, 29) Wärmeaustauschbereich wieder zu einer einzigen Leitung (34) vereinen.

11. System nach einem der Ansprüche 2, 3, 9 oder 10, wobei die Quelle für Boil-off-Gas der erste Speicher (11) oder ein Speicher, eine Leitung oder ein Sammelpunkt ist, der bzw. die mit dem ersten Speicher (11) verbunden ist.

12. Verfahren nach Anspruch 3 oder einem davon abhängigen Verfahrensanspruch, wobei der Schritt des Übertragens von Wärme von dem Strom aus gasförmigem Boil-off-Gas auf den Strom aus verflüssigtem Kohlenwasserstoffgas aus dem Speicher (11) für verflüssigtes Kohlenwasserstoffgas ferner Folgendes umfasst:

Übertragen von Wärme von dem Strom aus gasförmigem Boil-off-Gas auf das Wärmeträgerfluid in dem geschlossen Kühlkreislauf; und

Übertragen von Wärme von dem Wärmeträgerfluid in dem geschlossenen Kühlkreislauf auf den Strom aus verflüssigtem Kohlenwasserstoffgas; oder System nach Anspruch 3 oder einem davon abhängigen Systemanspruch, wobei die erste (30, 33, 34) und zweite (1, 2) Anordnung aus Leitungen derart angeordnet sind, dass Wärme zwischen der ersten (30, 33, 34) und zweiten (1, 2) Anordnung aus Leitungen über den geschlossenen Kühlkreislauf übertragen wird, wobei:
die fünfte (39, 41) und zweite (1, 2) Anordnung aus Leitungen derart angeordnet sind, dass Wärme von dem Strom aus gasförmigem Boil-off-Gas, der durch die zweite Anordnung aus Leitungen (1, 2) strömt, auf das Wärmeträgerfluid übertragen wird, das durch die fünfte Anordnung aus Leitungen (39, 41) strömt.

13. System nach Anspruch 9, wobei die zweite Abzweigung derart angeordnet ist, dass Wärme von dem Wärmeträgerfluid, das durch die fünfte Anordnung aus Leitungen (39, 41) strömt, auf den Strom aus verflüssigtem Kohlenwasserstoffgas übertragen wird, der durch die zweite Abzweigung strömt.

14. Verfahren nach einem der Ansprüche 1, 3 bis 8 oder 12, ferner umfassend ein Aufbereiten eines Stroms aus Umgebungsluft zur Bildung des Stroms aus gasförmigem tiefkaltem Fluid, wobei der Schritt des Aufbereitens des Stroms aus Umgebungsluft einen oder beide der folgenden Schritten umfasst:

Filtern des Stroms aus Umgebungsluft zum Entfeuchten, zum Entfernen von Kohlendioxid und/oder Kohlenwasserstoffen; und

Verdichten des Stroms aus Umgebungsluft; oder System nach einem der Ansprüche 2, 3, 9 bis 11, 12 oder 13, wobei der Strom aus gasförmigem tiefkaltem Fluid Luft ist und wobei die dritte Anordnung aus Leitungen (12, 21) ferner umfasst:

ein Filtersystem zum Entfeuchten eines Stroms aus Umgebungsluft, zum Entfernen von Kohlendioxid und/oder Kohlenwasserstoffen aus einem Strom aus Umgebungsluft; und

einen Verdichter zum Verdichten eines Stroms aus Umgebungsluft.

15. Verfahren nach einem der Ansprüche 1, 3 bis 8, 12 oder 14, ferner umfassend Leiten des Stroms aus verflüssigtem tiefkaltem Fluid durch einen Abscheider, bevor er in den Tank für das verflüssigte tiefkalte Fluid strömt, damit restliche Dampfphase aus dem Strom aus verflüssigtem tiefkaltem Fluid abgetrennt wird, und Zurückleiten der restlichen Dampfphase zu dem Strom aus gasförmigem tiefkaltem Fluid; oder System nach einem der Ansprüche 2, 3, 9 bis 11, oder 12 bis 14, wobei die dritte Anordnung aus Leitungen (12, 21) ferner einen Abscheider in Strömungsrichtung vor dem zweiten Speicher (24) zum Extrahieren von restlicher Dampfphase aus dem Strom aus verflüssigtem tiefkaltem Fluid, der durch die dritte Anordnung aus Leitungen (12, 21) strömt, bevor er in den zweiten Speicher (24) strömt, und eine Rückführleitung umfasst, die so angeordnet ist, dass sie die restliche Dampfphase, die aus dem Strom aus verflüssigtem tiefkaltem Fluid extrahiert ist, zu dem Strom aus gasförmigem tiefkaltem Fluid leitet, der durch die dritte Anordnung aus Leitungen (12, 21) strömt.

16. Verfahren nach einem der Ansprüche 1, 3 bis 8, 12, 14 oder 15, ferner umfassend Pumpen des Stroms aus verflüssigtem tiefkaltem Fluid aus dem Speicher (24) für verflüssigtes tiefkaltes Fluid zwecks Erhöhung seinen Drucks vor dem Schritt des Übertragens von Wärme von dem Strom aus gasförmigem Boil-off-Gas auf den Strom aus verflüssigtem tiefkaltem Fluid aus dem Speicher (24) für verflüssigtes tiefkaltes Fluid; oder System nach einem der Ansprüche 2, 3, 9 bis 11, oder 12 bis 15, wobei die zweite (1, 2) und vierte (52) Anordnung aus Leitungen derart angeordnet sind, dass Wärme zwischen der zweiten (1, 2) und vierten (52) Anordnung aus Leitungen in einem dritten Wärmeaustauschbereich (43) übertragen wird, und wobei die vierte Anordnung aus Leitungen (52) ferner eine Pumpe in Strömungsrichtung vor dem dritten Wärmeaustauschbereich (43) umfasst, zum Pumpen des Stroms aus verflüssigtem tiefkaltem Fluid, der durch die vierte Anordnung aus Leitungen (52) strömt, bevor er durch den dritten Wärmeaustauschbereich (43) strömt.

17. Verfahren nach einem der Ansprüche 1, 3 bis 8, 12 oder 14 bis 16, wobei der Schritt des Übertragens von Wärme von dem Strom aus gasförmigem Boil-off-Gas auf den Strom aus verflüssigtem tiefkaltem Fluid aus dem Speicher (24) für verflüssigtes tiefkaltes Fluid, derart, dass der Strom aus verflüssigtem tiefkaltem Fluid seinen Aggregatzustand von einem verflüssigten tiefkalten Fluid in ein gasförmiges tiefkaltes Fluid ändert, einen zweiten Strom aus gasförmigem tiefkaltem Fluid bewirkt, wobei das Verfahren ferner folgende Schritte umfasst: Entspannen des zweiten Stroms aus gasförmigem tiefkaltem Fluid, damit aus dem Strom Arbeit gewonnen wird; Überhitzen des zweiten Stroms aus gasförmigem tiefkaltem Fluid vor einer oder mehreren Entspannungsstufen; und Umwandeln der aus dem zweiten Strom gewonnenen Arbeit in Strom; wobei der Schritt des Entspannens des zweiten Stroms aus gasförmigem tiefkaltem Fluid zum Gewinnen von Arbeit aus dem zweiten Strom in einer einstufigen Entspannungsvorrichtung, einer zweistufigen Entspannungsvorrichtung oder einer mehrstufigen Entspannungsvorrichtung durchgeführt wird; oder System nach Anspruch 16, wobei der dritte Wärmeaustauschbereich (43) derart eingerichtet ist, dass von dem Strom aus gasförmigem Boil-off-Gas, der durch die zweite Anordnung aus Leitungen (1, 2) strömt, Wärme auf den Strom aus verflüssigtem tiefkaltem Fluid übertragen wird, der durch die vierte Anordnung aus Leitungen (52) strömt, und so ein zweiter Strom aus gasförmigem tiefkaltem Fluid erzeugt wird, und wobei die vierte Anordnung aus Leitungen (52) ferner eine Entspannungsvorrichtung zum Entspannen des zweiten Stroms aus gasförmigem tiefkaltem Fluid und Gewinnen von Arbeit aus dem zweiten Strom aus tiefkaltem Fluid umfasst;
wobei die Entspannungsvorrichtung eine einstufige Entspannungsvorrichtung, eine zweistufige Entspannungsvorrichtung oder eine mehrstufige Entspannungsvorrichtung ist;
wobei die vierte Anordnung aus Leitungen (52) mit einem oder mehreren Überhitzern verbunden ist und wobei jeder Überhitzer entweder der ersten Stufe der Entspannungsvorrichtung vorgeschaltet ist oder sich zwischen Stufen der Entspannungsvorrichtung befindet.

18. System nach einem der Ansprüche 2, 3, 9, 10 oder 11, ferner umfassend einen oder mehrere Wärmetauscher (5, 13, 29, 43), wobei die erste (30, 33, 34), zweite (1, 2), dritte (12, 21) und vierte (52) Anordnung aus Leitungen derart angeordnet sind, dass Wärme von dem einen oder den mehreren Wärmetauschern (5, 13, 29, 43) zwischen der ersten (30, 33, 34) und dritten (12, 21) Anordnung aus Leitungen, zwischen der zweiten (1, 2) und vierten (52) Anordnung aus Leitungen übertragen wird.

19. System nach Anspruch 18, wenn es von Anspruch 3 oder einem davon abhängigen Anspruch abhängt, wobei die erste (30, 33, 34), zweite (1, 2), dritte (12, 21) und vierte (52) Anordnung aus Leitungen derart angeordnet sind, dass Wärme von dem einen oder den mehreren Wärmetauschern (5, 13, 29, 43) zwischen der ersten (30, 33, 34) und zweiten (1, 2) Anordnung aus Leitungen übertragen wird.

20. System nach Anspruch 2 oder Verfahren nach Anspruch 1 oder einem davon abhängigen Anspruch, wobei der geschlossene Kühlkreislauf nach einem Einphasen-Brayton-Kreisprozess oder einem Zweiphasen-Rankine-Kreisprozess arbeitet.

21. System nach Anspruch 2 oder Verfahren nach Anspruch 1 oder einem davon abhängigen Anspruch, wobei das Wärmeträgerfluid Stickstoff oder Propan ist.

22. System nach einem der Ansprüche 2, 3 oder 9 bis 21 oder Verfahren nach einem der Ansprüche 1, 3 bis 8, 12, 14 bis 17, 20 oder 21, wobei das tiefkalte Fluid Stickstoff oder Luft, vorzugsweise Umgebungsluft ist.

23. System nach einem der Ansprüche 2 bis 3 oder 9 bis 22 oder Verfahren nach einem der Ansprüche 1, 3 bis 8, 12, 14 bis 17, 20, 21 oder 22, wobei das verflüssigte Kohlenwasserstoffgas Flüssigerdgas (LNG) ist.

Revendications

1. Procédé pour la liquéfaction de gaz d'évaporation, comprenant :

le stockage d'un gaz d'hydrocarbures liquéfié dans un stockage de gaz d'hydrocarbures liquéfié (11) ;

le traitement d'un flux de fluide cryogénique gazeux et d'un flux de gaz d'hydrocarbures liquéfié provenant du stockage de gaz d'hydrocarbures liquéfié (11), de façon telle que :

a) le flux de gaz d'hydrocarbures liquéfié subit un changement de phase d'un gaz d'hydrocarbures liquéfié en un gaz d'hydrocarbures gazeux ; et

b) le flux de fluide cryogénique gazeux subit un changement de phase d'un fluide cryogénique gazeux en un fluide cryogénique liquéfié ;

dans lequel l'étape de traitement comprend le transfert de chaleur du flux de fluide cryogénique gazeux vers le flux de gaz d'hydrocarbures liquéfié provenant du stockage de gaz d'hydrocarbures liquéfié (11) ;

le stockage du fluide cryogénique liquéfié dans un stockage de fluide cryogénique liquéfié (24) ;

le traitement d'un flux de gaz d'évaporation gazeux et d'un flux de fluide cryogénique liquéfié provenant du stockage de fluide cryogénique liquéfié (24) de façon telle que :

a) le flux de fluide cryogénique liquéfié subit un changement de phase d'un fluide cryogénique liquéfié en un fluide cryogénique gazeux ; et

b) le flux de gaz d'évaporation gazeux subit un changement de phase d'un gaz d'évaporation gazeux en un gaz d'évaporation liquéfié ;

dans lequel l'étape de traitement comprend le transfert de chaleur du flux de gaz d'évaporation gazeux vers le flux de fluide cryogénique liquéfié provenant du stockage de fluide cryogénique liquéfié (24) ;

le stockage du gaz d'évaporation liquéfié dans le stockage de gaz d'hydrocarbures liquéfié (11) ;

le réglage du débit du flux de fluide cryogénique gazeux sur la base au moins en partie du débit du flux de gaz d'hydrocarbures liquéfié provenant du stockage de gaz d'hydrocarbures liquéfié (11) ; et

indépendamment le réglage du débit du flux de fluide cryogénique liquéfié provenant du stockage de fluide cryogénique liquéfié (24) sur la base au moins en partie du débit du flux de gaz d'évaporation gazeux ;

le procédé étant caractérisé en ce que
l'étape de transfert de chaleur du flux de fluide cryogénique gazeux vers le flux de gaz d'hydrocarbures liquéfié provenant du stockage de gaz d'hydrocarbures (11) comprend en outre :

le transfert de chaleur du flux de fluide cryogénique gazeux vers un fluide caloporteur présent dans un circuit de réfrigération en boucle fermée (37, 39, 40, 41) et le refroidissement du fluide cryogénique gazeux à une température au-dessous de la température de saturation du gaz d'hydrocarbures liquéfié ; et

le transfert de chaleur du fluide caloporteur présent dans le circuit de réfrigération en boucle fermée vers le flux de gaz d'hydrocarbures liquéfié.

2. Système pour la liquéfaction de gaz d'évaporation, comprenant :

un premier stockage (11) pour le stockage de gaz d'hydrocarbures liquéfié ;

un premier agencement de conduites (30, 33, 34) raccordées au premier stockage (11) et à un réseau de gaz d'hydrocarbures pour l'acheminement de gaz d'hydrocarbures vers un destinataire ;

un deuxième agencement de conduites (1, 2) raccordées à une source de gaz d'évaporation et au premier stockage (11) pour l'acheminement de gaz d'évaporation liquéfié vers le premier stockage (11) ;

un second stockage (24) pour le stockage d'un fluide cryogénique liquéfié ;

un troisième agencement de conduites (12, 21) raccordées à une source de fluide cryogénique gazeux et au second stockage (24) pour l'acheminement de fluide cryogénique liquéfié vers le second stockage (24) ;

un quatrième agencement de conduites (52) raccordées au second stockage (24) pour l'acheminement de fluide cryogénique provenant du second stockage (24) ;

dans lequel :

les premier (30, 33, 34) et troisième (12, 21) agencements de conduites sont agencés de façon telle que de la chaleur est transférée d'un flux de fluide cryogénique gazeux passant dans le troisième agencement de conduites (12, 21) vers un flux de gaz d'hydrocarbures liquéfié passant dans le premier agencement de conduites (30, 33, 34) ;
les deuxième (1, 2) et quatrième (52) agencements de conduites sont agencés de façon telle que de la chaleur est transférée d'un flux de gaz d'évaporation gazeux passant dans le deuxième agencement de conduites (1, 2) vers un flux de fluide cryogénique liquéfié passant dans le quatrième agencement de conduites (52) ; et

un dispositif de réglage configuré pour :

a) régler le débit du flux débit du flux de fluide cryogénique gazeux passant le troisième agencement de conduites (12, 21) sur la base au moins en partie du débit du flux de gaz d'hydrocarbures liquéfié passant dans le premier agencement de conduites (30, 33, 34) ; et

b) indépendamment régler le débit du flux de fluide cryogénique liquéfié passant dans le quatrième agencement de conduites (52) sur la base au moins en partie du débit du flux de gaz d'évaporation gazeux passant dans le deuxième agencement de conduites (1, 2) ;

et caractérisé en ce que le système comprend en outre
un cinquième agencement de conduites (39, 41) qui est agencé sous forme d'un circuit de réfrigération en boucle fermée (37, 39, 40, 41) comprenant un fluide caloporteur passant dans le cinquième agencement de conduites, dans lequel :
les premier (30, 33, 34) et troisième (12, 21) agencements de conduites sont agencés de façon telle que de la chaleur est transférée entre les premier (30, 33, 34) et troisième (12, 21) agencements de conduite par l'intermédiaire du circuit de réfrigération en boucle fermée (37, 39, 40, 41), dans lequel :

les cinquième (39, 41) et troisième (12, 21) agencements de conduites sont agencés de façon telle que de la chaleur est transférée du flux de fluide cryogénique gazeux passant dans le troisième agencement de conduites (12, 21) vers le fluide caloporteur passant dans le cinquième agencement de conduites (39, 41) ; et

les cinquième (39, 41) et premier (30, 33, 34) agencements de conduites sont agencés de façon telle que de la chaleur est transférée du fluide caloporteur passant dans le cinquième agencement de conduites (39, 41) vers le flux de gaz d'hydrocarbures liquéfié passant dans le premier (30, 33, 34) agencement de conduites.

3. Procédé selon la revendication 1, comprenant en outre l'étape de traitement du flux de gaz d'évaporation gazeux et du flux de gaz d'hydrocarbures liquéfié provenant du stockage de gaz d'hydrocarbures liquéfié (11) de façon telle que :

a) le flux de gaz d'hydrocarbures liquéfié subit un changement de phase d'un gaz d'hydrocarbures liquéfié en un gaz d'hydrocarbures gazeux ; et

b) le flux de gaz d'évaporation gazeux subit un changement de phase d'un gaz d'évaporation gazeux en un gaz d'évaporation liquéfié ;

dans lequel l'étape de traitement comprend le transfert de chaleur du flux de gaz d'évaporation gazeux vers le flux de gaz d'hydrocarbures liquéfié provenant du stockage de gaz d'hydrocarbures liquéfié (11) ; ou système selon la revendication 2, dans lequel les premier (30, 33, 34) et deuxième (1, 2) agencements de conduites sont agencés de façon telle que de la chaleur est transférée du flux de gaz d'évaporation gazeux passant dans le deuxième agencement de conduites (1, 2) vers le flux de gaz d'hydrocarbures liquéfié passant dans le premier agencement de conduites (30, 33, 34).

4. Procédé selon la revendication 3, dans lequel les étapes de :

a) transfert de chaleur du flux de fluide cryogénique gazeux vers le flux de gaz d'hydrocarbures liquéfié provenant du stockage de gaz d'hydrocarbures liquéfié (11) ; et

b) transfert de chaleur du flux de gaz d'évaporation gazeux vers le flux de gaz d'hydrocarbures liquéfié provenant du stockage de gaz d'hydrocarbures liquéfié (11) ;

sont simultanées.

5. Procédé selon l'une quelconque des revendications 1, 3 ou 4, dans lequel l'étape de traitement du flux de fluide cryogénique gazeux et du flux de gaz d'hydrocarbures liquéfié comprend en outre les étapes de :

détente du flux de fluide cryogénique gazeux après le transfert de chaleur et

compression du flux de fluide cryogénique gazeux avant le transfert de chaleur ;

dans lequel l'étape de compression du flux de fluide cryogénique gazeux avant le transfert de chaleur comprend la compression du flux à une pression supercritique.

6. Procédé selon la revendication 5, comprenant en outre les étapes de passage du flux de gaz d'hydrocarbures liquéfié dans des première (32) et seconde (28) dérivations ;
dans lequel l'étape de transfert de chaleur du flux de fluide cryogénique gazeux vers le flux de gaz d'hydrocarbures liquéfié provenant du stockage de gaz d'hydrocarbures liquéfié (11) comprend en outre :

le transfert de chaleur vers un flux de gaz d'hydrocarbures liquéfié dans la première dérivation (32) à partir du flux de fluide cryogénique gazeux avant la compression ; et

le transfert de chaleur vers un flux de gaz d'hydrocarbures liquéfié dans la seconde dérivation (28) à partir du flux de fluide cryogénique gazeux après la compression par l'intermédiaire du circuit de réfrigération en boucle fermée (37, 39, 40, 41).

7. Procédé selon l'une quelconque des revendications 1 ou 3 à 6, comprenant en outre l'étape d'acheminement du flux de gaz d'hydrocarbures gazeux vers un destinataire ;
dans lequel le destinataire en est un ou plusieurs parmi : un réseau de tuyaux d'hydrocarbures ; une centrale électrique ; et un consommateur de gaz d'hydrocarbures gazeux.

8. Procédé selon l'une quelconque des revendications 1 ou 3 à 7, comprenant en outre l'étape de collecte du flux de gaz d'évaporation gazeux provenant du stockage de gaz d'hydrocarbures liquéfié (11) ;
dans lequel l'étape de collecte du flux de gaz d'évaporation gazeux comprend la collecte du gaz d'évaporation à partir d'un stockage ou d'un point de collecte raccordé au stockage de gaz d'hydrocarbures liquéfié (11).

9. Système selon la revendication 2 ou la revendication 3, dans lequel le troisième agencement de conduites (12, 21) comprend un compresseur (15) pour la compression du flux de fluide cryogénique gazeux à une pression supercritique et un détendeur (22) pour la détente du flux de fluide cryogénique à pression supercritique pour condenser et former un liquide cryogénique après échange de chaleur avec le fluide caloporteur passant dans le cinquième agencement de conduites (39, 41) ; et dans lequel le premier agencement de conduites (30, 33, 34) comprend une première dérivation (32) et une seconde dérivation (28) ;
la première dérivation (32) étant agencée de façon telle que de la chaleur est transférée vers un flux de gaz d'hydrocarbures liquéfié passant dans la première dérivation (32) à partir du flux de fluide cryogénique gazeux passant dans le troisième agencement de conduites (12, 21) au niveau d'une première zone d'échange de chaleur (13) en amont du compresseur (15) ; et
la seconde dérivation (30) étant agencée de façon telle que de la chaleur est transférée vers un flux de gaz d'hydrocarbures liquéfié passant dans la seconde dérivation à partir du flux de fluide cryogénique gazeux passant dans le troisième agencement de conduites (12, 21) au niveau d'une deuxième zone d'échange de chaleur (5, 29) en aval du compresseur (15) par l'intermédiaire du circuit de réfrigération en boucle fermée (37, 39, 40, 41).

10. Système selon la revendication 9, dans lequel les première (32) et seconde (28) dérivations partent d'une seule conduite (27) en amont des première et deuxième zones d'échange de chaleur et se réunissent en une seule conduite (34) en aval des première (13) et deuxième (5, 29) zones d'échange de chaleur.

11. Système selon l'une quelconque des revendications 2, 3, 9 ou 10, dans lequel la source de gaz d'évaporation est le premier stockage (11) ou un stockage, une conduite ou un point de collecte raccordés au premier stockage (11) .

12. Procédé selon la revendication 3, ou une quelconque revendication de procédé dépendante de celle-ci, dans lequel l'étape de transfert de chaleur du flux de gaz d'évaporation gazeux vers le flux de gaz d'hydrocarbures liquéfié provenant du stockage de gaz d'hydrocarbures liquéfié (11) comprend en outre :

le transfert de chaleur du flux de gaz d'évaporation gazeux vers le fluide caloporteur présent dans le circuit de réfrigération en boucle fermée ; et

le transfert de chaleur du fluide caloporteur présent dans le circuit de réfrigération en boucle fermée vers le flux de gaz d'hydrocarbures liquéfié ; ou système selon la revendication 3, ou une quelconque revendication de système dépendante de celle-ci, dans lequel les premier (30, 33, 34) et deuxième (1, 2) agencements de conduites sont agencés de façon telle que de la chaleur est transférée entre les premier (30, 33, 34) et deuxième (1, 2) agencements de conduites par l'intermédiaire du circuit de réfrigération en boucle fermée, dans lequel :

les cinquième (39, 41) et deuxième (1, 2) agencements de conduites sont agencés de façon telle que de la chaleur est transférée du flux de gaz d'évaporation gazeux passant dans le deuxième agencement de conduites (1, 2) vers le fluide caloporteur passant dans le cinquième agencement de conduites (39, 41).

13. Système selon la revendication 9, dans lequel la seconde dérivation est agencée de façon telle que de la chaleur est transférée du fluide caloporteur passant dans le cinquième agencement de conduites (39, 41) vers le flux de gaz d'hydrocarbures liquéfié passant dans la seconde dérivation.

14. Procédé selon l'une quelconque des revendications 1, 3 à 8 ou 12, comprenant en outre le traitement d'un flux d'air ambiant pour former le flux de fluide cryogénique gazeux, dans lequel l'étape de traitement du flux d'air ambiant comprend l'une des étapes de :

filtration du flux d'air ambiant pour éliminer de l'humidité, du dioxyde de carbone et/ou des hydrocarbures ; et

compression du flux d'air ambiant,
ou les deux, ou système selon l'une quelconque des revendications 2, 3, 9 à 11, 12 ou 13, dans lequel le flux de fluide cryogénique gazeux est de l'air et dans lequel le troisième agencement de conduites (12, 21) comprend en outre l'un de :

un système de filtration pour l'élimination d'humidité, de dioxyde de carbone et/ou d'hydrocarbures d'un flux d'air ambiant ; et

un compresseur pour la compression d'un flux d'air ambiant.

15. Procédé selon l'une quelconque des revendications 1, 3 à 8, 12 ou 14, comprenant en outre le passage du flux de fluide cryogénique liquéfié dans un séparateur avant qu'il entre dans le réservoir de fluide cryogénique liquéfié pour séparer toute phase vapeur résiduelle du flux de fluide cryogénique liquéfié et le renvoi de la phase vapeur résiduelle vers le flux de fluide cryogénique gazeux ; ou système selon l'une quelconque des revendications 2, 3, 9 à 11 ou 12 à 14, dans lequel le troisième agencement de conduites (12, 21) comprend en outre un séparateur en amont du second stockage (24) pour l'extraction de toute phase vapeur résiduelle du flux de fluide cryogénique liquéfié passant dans le troisième agencement de conduites (12, 21) avant qu'il entre dans le second stockage (24) et une conduite de retour agencée pour envoyer la phase vapeur résiduelle extraite du flux de fluide cryogénique liquéfié vers le flux de fluide cryogénique gazeux passant dans le troisième agencement de conduites (12, 21).

16. Procédé selon l'une quelconque des revendications 1, 3 à 8, 12, 14 ou 15, comprenant en outre le pompage du flux de fluide cryogénique liquéfié provenant du stockage de fluide cryogénique liquéfié (24) pour augmenter sa pression avant l'étape de transfert de chaleur du flux de gaz d'évaporation gazeux vers le flux de fluide cryogénique liquéfié provenant du stockage de fluide cryogénique liquéfié (24) ; ou système selon l'une quelconque des revendications 2, 3, 9 à 11 ou 12 à 15, dans lequel les deuxième (1, 2) et quatrième (52) agencements de conduites sont agencés de façon telle que de la chaleur est transférée entre les deuxième (1, 2) et quatrième (52) agencements de conduites au niveau d'une troisième zone d'échange de chaleur (43) et dans lequel le quatrième agencement de conduites (52) comprend en outre une pompe en amont de la troisième zone d'échange de chaleur (43) pour le pompage du flux de fluide cryogénique liquéfié passant dans le quatrième agencement de conduites (52) avant qu'il passe dans la troisième zone d'échange de chaleur (43).

17. Procédé selon l'une quelconque des revendications 1, 3 à 8, 12 ou 14 à 16, dans lequel l'étape de transfert de chaleur du flux de gaz d'évaporation gazeux vers le flux de fluide cryogénique liquéfié provenant du stockage de fluide cryogénique liquéfié (24) de façon telle que le flux de fluide cryogénique liquéfié subit un changement de phase d'un fluide cryogénique liquéfié en un fluide cryogénique gazeux résulte en un second flux de fluide cryogénique gazeux, le procédé comprenant en outre les étapes de détente du second flux de fluide cryogénique gazeux pour extraire du travail à partir du flux ; surchauffe du second flux de fluide cryogénique gazeux avant un ou plusieurs étages de détente ; et conversion du travail extrait du second flux en électricité ; dans lequel l'étape de détente du second flux de fluide cryogénique gazeux pour extraire du travail à partir du second flux est effectuée dans dispositif de détente à un seul étage, un dispositif de détente à deux étages ou un dispositif de détente à plusieurs étages ; ou système selon la revendication 16, dans lequel la troisième zone d'échange de chaleur (43) est configurée de façon telle que de la chaleur est transférée du flux de gaz d'évaporation gazeux passant dans le deuxième agencement de conduites (1, 2) vers le flux de fluide cryogénique liquéfié passant dans le quatrième agencement de conduites (52) pour produire un second flux de fluide cryogénique gazeux et dans lequel le quatrième agencement de conduites (52) comprend en outre un dispositif de détente pour la détente du second flux de fluide cryogénique gazeux et l'extraction de travail à partir du second flux de fluide cryogénique ; dans lequel le dispositif de détente est un dispositif de détente à un seul étage, un dispositif de détente à deux étages ou un dispositif de détente à plusieurs étages ;
dans lequel le quatrième agencement de conduites (52) est raccordé à un ou plusieurs surchauffeurs et dans lequel chaque surchauffeur est soit en amont du premier étage du dispositif de détente soit entre des étages du dispositif de détente.

18. Système selon l'une quelconque des revendications 2, 3, 9, 10 ou 11, comprenant en outre un ou plusieurs échangeurs de chaleur (5, 13, 29, 43) dans lequel les premier (30, 33, 34), deuxième (1, 2), troisième (12, 21) et quatrième (52) agencements de conduites sont agencés de façon telle que de la chaleur est transférée entre les premier (30, 33, 34) et troisième (12, 21) agencements de conduites, entre les deuxième (1, 2) et quatrième (52) agencements de conduites par le ou les échangeurs de chaleur (5, 13, 29, 43).

19. Système selon la revendication 18, lorsqu'elle est dépendante de la revendication 3 ou d'une quelconque revendication dépendante de celle-ci, dans lequel les premier (30, 33, 34), deuxième (1, 2), troisième (12, 21) et quatrième (52) agencements de conduites sont agencés de façon telle que de la chaleur est transférée entre les premier (30, 33, 34) et deuxième (1, 2) agencements de conduites par le ou les échangeurs de chaleur (5, 13, 29, 43).

20. Système selon la revendication 2 ou procédé selon la revendication 1, ou une quelconque revendication dépendante de celles-ci, dans lesquels le circuit de réfrigération en boucle fermée fonctionne à l'aide de l'un d'un cycle de Brayton à une seule phase et d'un cycle de Rankine à deux phases.

21. Système selon la revendication 2 ou procédé selon la revendication 1, ou une quelconque revendication dépendante de celles-ci, dans lesquels le fluide caloporteur est l'un de l'azote ou du propane.

22. Système selon l'une quelconque des revendications 2, 3 ou 9 à 21 ou procédé selon l'une quelconque des revendications 1, 3 à 8, 12, 14 à 17, 20 ou 21, dans lesquels le fluide cryogénique est l'un de l'azote ou de l'air, de préférence l'air ambiant.

23. Système selon l'une quelconque des revendications 2 à 3 ou 9 à 22 ou procédé selon l'une quelconque des revendications 1, 3 à 8, 12, 14 à 17, 20, 21 ou 22, dans lesquels le gaz d'hydrocarbures liquéfié est du gaz naturel liquéfié (GNL).

Drawing