Reliquefaction of boil-off from liquefied natural gas

Information

  • Patent Grant
  • 6672104
  • Patent Number
    6,672,104
  • Date Filed
    Wednesday, March 26, 2003
    21 years ago
  • Date Issued
    Tuesday, January 6, 2004
    20 years ago
Abstract
A process is provided for converting a boil-off stream comprising methane to a liquid having a preselected bubble point temperature. The boil-off stream is pressurized, then cooled, and then expanded to further cool and at least partially liquefy the boil-off stream. The preselected bubble point temperature of the resulting pressurized liquid is obtained by performing at least one of the following steps: before, during, or after the process of liquefying the boil-off stream, removing from the boil-off stream a predetermined amount of one or more components, such as nitrogen, having a vapor pressure greater than the vapor pressure of methane, and before, during, or after the process of liquefying the boil-off stream, adding to the boil-off stream one or more additives having a molecular weight heavier than the molecular weight of methane and having a vapor pressure less than the vapor pressure of methane.
Description




FIELD OF THE INVENTION




This invention relates generally to an improved process for reliquefaction of boil-off from methane-rich liquefied gas such as boil-off from liquefied natural gas (“LNG”) or boil-off from pressurized liquefied natural gas (“PLNG”).




BACKGROUND OF THE INVENTION




Because of its clean burning qualities and convenience, natural gas has become widely used in recent years. Many sources of natural gas are located in remote areas, great distances from any commercial markets for the gas. Sometimes a pipeline is available for transporting produced natural gas to a commercial market. When pipeline transportation is not feasible, produced natural gas is often processed into liquefied natural gas (“LNG”) for transport to market at or near ambient pressure and at a temperature of about −162° C. (−260° F.).




The source gas for making LNG is typically obtained from a crude oil well (associated gas) or from a gas well (non-associated gas). Associated gas occurs either as free gas or as gas in solution in crude oil. Although the composition of natural gas varies widely from field to field, the typical gas contains the hydrocarbon methane (C


1


) as a major component. The natural gas stream may also contain the hydrocarbon ethane (C


2


), higher hydrocarbons (C


2+


), and minor amounts of contaminants such as carbon dioxide (CO


2


), hydrogen sulfide (H


2


S), nitrogen (N


2


), iron sulfide, wax, and crude oil. The solubilities of the contaminants vary with temperature, pressure, and composition. At cryogenic temperatures, CO


2


, water, other contaminants, and certain heavy molecular weight hydrocarbons can form solids, which can potentially plug flow passages in liquefaction process equipment. These potential difficulties can be avoided by removing such contaminants and heavy hydrocarbons from the natural gas stream prior to liquefaction.




It has also been proposed to transport natural gas at temperatures above −112° C. (−170° F.) and at pressures sufficient for the liquid to be at or below its bubble point temperature. This pressurized liquid natural gas is referred to in this specification as “PLNG” to distinguish it from LNG, which is transported at near atmospheric pressure and at a temperature of about −162° C. (−260° F.).




Because PLNG typically contains a mixture of low molecular weight hydrocarbons and other substances, the exact bubble point temperature of PLNG is a function of its composition. For most natural gas compositions, the bubble point pressure of the natural gas at temperatures above −112° C. (−170° F.) will be above 1,380 kPa (200 psia). One of the advantages of producing and shipping PLNG at a warmer temperature than LNG is that PLNG can contain considerably more C


2+


components than can be tolerated in most LNG applications.




Depending upon market prices for ethane, propane, butanes, and heavier hydrocarbons (collectively referred to herein as “NGL products”), it may be economically desirable to transport the NGL products with the PLNG and to sell them as separate products. International Publication No. WO 90/00589 (Brundige) discloses a process of transporting pressurized liquid heavy gas containing butane and heavier components, including condensable components that are deliberately and intentionally left in the liquefied natural gas. In the Brundige process, basically the entire natural gas composition, regardless of its origin or original composition, is liquefied without removal of various gas components. This is accomplished by adding to the natural gas an organic conditioner, preferably C


2


to C


5


hydrocarbons to change the composition of the natural gas and thereby form an altered gas that is in a liquid state at a selected storage temperature and pressure. Brundige allows the liquefied product to be transported in a single vessel under pressurized conditions at a higher temperature than conventional LNG.




In the storage, transportation, and handling of PLNG, there can be a considerable amount of boil-off, which boil-off is primarily in the gaseous or vapor phase. In many applications in which boil-off is produced, it is desirable to reliquefy the boil-off and combine it with the liquid that produced the boil-off. PLNG boil-off can typically be reliquefied using the same process used to produce PLNG. However, since PLNG often contains an appreciable quantity of nitrogen, this nitrogen will, as a result of its lower boiling point compared with other constituents of natural gas, evaporate preferentially and form a significant portion of the boil-off. For example, for PLNG at 450 psia containing 0.1% nitrogen, boil-off may contain as much as 3% nitrogen. At a given pressure, reliquefaction of the boil-off will therefore require cooling of the boil-off to a lower temperature than required to liquefy the liquid from which the boil-off was produced. Various reliquefaction processes have been proposed for handling nitrogen-rich boil-off.




U.S. Pat. No. 3,857,245 (Jones) discloses a process of condensing a nitrogen-containing boil-off in which LNG is injected into the nitrogen-containing boil-off vapor and the combined mixture is then condensed. The injection of the LNG into the nitrogen-containing boil-off increases the volume of vapor that must be reliquefied.




U.S. Pat. No. 6,192,705 (Kimble) discloses a process of passing boil-off through a heat exchanger followed by compressing and cooling stages, and then recycling the boil-off back through the heat exchanger. The compressed, cooled, and then heated boil-off is subsequently expanded and passed to a gas-liquid separator for removal of liquefied boil-off. The liquefied boil-off is then combined with a second liquefied gas stream to produce a desired product stream.




One problem encountered with reliquefaction processes proposed in the past is that the reliquefied boil-off may have a lower (colder) bubble point temperature than that of the bulk cargo liquid that produced the boil-off. This lower temperature can be undesirable if it exceeds the lower allowable limit of the operating temperature of the transport containers. A need therefore exists for an improved process for re-liquefying PLNG boil-off to overcome the temperature disparity between the bulk bubble point temperature of the liquefied cargo and the bubble point temperature of the liquefied boil-off.




SUMMARY OF THE INVENTION




This invention relates to a method of converting a boil-off stream comprising methane to a liquid having a preselected bubble point temperature, comprising the steps of: (a) pressurizing the boil-off stream; (b) cooling the pressurized boil-off stream of step (a); (c) expanding the cooled, pressurized boil-off stream of step (b), thereby producing pressurized liquid; and (d) obtaining the preselected bubble point temperature of the pressurized liquid by performing at least one of the following steps:




i. before, during, or after one or more of steps (a) to (c), removing from the boil-off stream a first predetermined amount of one or more components having a vapor pressure greater than the vapor pressure of methane, and




ii. before, during, or after one or more of steps (a) to (c), adding to the boil-off stream a second predetermined amount of one or more additives having a molecular weight heavier than the molecular weight of methane and having a vapor pressure less than the vapor pressure of methane,




wherein the first predetermined amount of the one or more components removed and the second predetermined amount of the one or more additives added are controlled to obtain the preselected bubble point temperature of the pressurized liquid. If desired, the multi-component boil-off stream can be warmed prior to the first pressurization. In one embodiment of the method of this invention, the one or more components removed from the boil-off stream comprise nitrogen. In one embodiment of this invention, the one or more additives added to the boil-off stream comprise one or more C


2+


hydrocarbons. One embodiment of this invention further comprises combining the pressurized liquid having the preselected bubble point temperature with a second pressurized liquid having substantially the same bubble point temperature; and sometimes the second pressurized liquid produced the boil-off stream being liquefied. One embodiment of this invention further comprises before step (d), determining an amount of a first component of said one or more components to be removed from the boil-off stream, the first component having a vapor pressure greater than the vapor pressure of methane, and determining an amount of a first additive of said one or more additives to be added to the boil-off stream, the first additive having a molecular weight heavier than the molecular weight of methane and having a vapor pressure less than the vapor pressure of methane, both of said determinations being performed by determining the composition of the boil-off stream and performing an equation of state analysis to determine a pressurized liquid composition needed to obtain the preselected bubble point temperature in said pressurized liquid at a preselected pressure. Another embodiment of this invention further comprises before step (d), determining the first predetermined amount of the one or more components to be removed from the boil-off stream, and determining the second predetermined amount of the one or more additives to be added to the boil-off stream, both of said determinations being performed by determining the composition of the boil-off stream and performing an equation of state analysis to determine a pressurized liquid composition needed to obtain the preselected bubble point temperature in said pressurized liquid at a preselected pressure.




In one embodiment, this invention relates to a method of converting a boil-off stream comprising methane to a liquid having a preselected bubble point temperature, comprising the steps of: (a) pressurizing the boil-off stream; (b) cooling the pressurized boil-off stream of step (a); (c) expanding the cooled, pressurized boil-off stream of step (b), thereby producing pressurized liquid; and (d) obtaining the preselected bubble point temperature of the pressurized liquid by performing at least one of the following steps:




i. before, during, or after one or more of steps (a) to (c), removing from the boil-off stream a first predetermined amount of nitrogen, and




ii. before, during, or after one or more of steps (a) to (c), adding to the boil-off stream a second predetermined amount of one or more C


2+


hydrocarbons,




wherein the first predetermined amount of the nitrogen removed and the second predetermined amount of the one or more C


2+


hydrocarbons added are controlled to obtain the preselected bubble point temperature of the pressurized liquid.




In one embodiment, this invention relates to a method of converting a boil-off stream comprising methane to a liquid having a preselected bubble point temperature, comprising the steps of: (a) pressurizing the boil-off stream; (b) cooling the pressurized boil-off stream of step (a); (c) expanding the cooled, pressurized boil-off stream of step (b), thereby producing pressurized liquid; and (d) obtaining the preselected bubble point temperature of the pressurized liquid by performing at least one of the following steps:




i. before, during, or after one or more of steps (a) to (c), removing from the boil-off stream a first predetermined amount of nitrogen, and




ii. before, during, or after one or more of steps (a) to (c), adding to the boil-off stream a second predetermined amount of one or more C


2+


hydrocarbons,




wherein the first predetermined amount of the nitrogen removed and the second predetermined amount of the one or more C


2+


hydrocarbons added are controlled to obtain the preselected bubble point temperature of the pressurized liquid, and further comprising before step (d), determining the first predetermined amount of the nitrogen to be removed from the boil-off stream, and determining the second predetermined amount of the one or more C


2+


hydrocarbons to be added to the boil-off stream, both of said determinations being performed by determining the composition of the boil-off stream and performing an equation of state analysis to determine a pressurized liquid composition needed to obtain the preselected bubble point temperature in said pressurized liquid at a preselected pressure.




The amount of the one or more components removed and the amount of the additives added is controlled to obtain the preselected bubble point temperature of the pressurized liquid. The additive(s) may comprise, for example without limiting this invention, C


2+


hydrocarbons (e.g., propane, butane, pentane, etc.) or carbon dioxide.











DESCRIPTION OF THE DRAWINGS




The advantages of the present invention will be better understood by referring to the following detailed description and the attached drawings in which:





FIG. 1

schematically illustrates one process for liquefaction of boil-off according to this invention;





FIG. 2

schematically illustrates an embodiment of this invention in which the boil-off liquefaction process uses a fractionating column.











While the invention will be described in connection with its preferred embodiments, it will be understood that the invention is not limited thereto. On the contrary, the invention is intended to cover all alternatives, modifications, and equivalents which may be included within the spirit and scope of the present disclosure, as defined by the appended claims.




DETAILED DESCRIPTION OF THE INVENTION




The process of the present invention liquefies a multi-component boil-off stream comprising methane to produce a liquefied boil-off stream having substantially the same bubble point temperature as the bubble point temperature of a pressurized liquefied gas to which the liquefied boil-off stream is to be added. This invention is particularly well suited for reliquefaction of boil-off from liquefied natural gas having a temperature above about −112° C. (−170° F.), which is referred to in this description as PLNG.




The process of this invention is particularly well suited for liquefying boil-off generated from PLNG that contains significant quantities of components other than methane, such as nitrogen and C


2+


hydrocarbons. PLNG boil-off will contain a higher concentration of lower-molecular weight components of the PLNG than will the PLNG itself. If PLNG contains nitrogen, the boil-off gas from the PLNG will typically contain a higher concentration of nitrogen. Similarly, if the PLNG contains C


2+


, the boil-off vapor will have a higher concentration of components that are more volatile than C


2+


, such as methane. Since a boil-off stream will typically have a different composition than the liquefied gas that produced the boil-off, when the boil-off is liquefied, it will typically have a different bubble point temperature than such liquefied gas at a given pressure.




The term “bubble point temperature” as used in this specification is the temperature at which a liquid begins to convert to gas at a given pressure. For example, if a certain volume of PLNG is held at constant pressure, but its temperature is increased, the temperature at which bubbles of gas begin to form in the PLNG is the bubble point temperature. At the bubble point temperature, PLNG is saturated liquid.




One embodiment of the present invention will now be described with reference to FIG.


1


. Boil-off feed stream


10


enters a liquefaction process by being passed through heat exchanger


20


, which utilizes boil-off feed stream


10


for cooling. Boil-off feed stream


10


can result from evaporation during storage, transportation, and/or handling of any liquefied gas (not shown in FIG.


1


). Boil-off feed stream


10


may come from LNG or from PLNG, for example.




Heat exchanger


20


may comprise one or more stages cooled by a conventional closed-cycle cooling loop


21


. For example, cooling loop


21


may comprise a single or multi-component refrigeration system suitable for providing refrigeration. This invention is not limited to any type of heat exchanger


20


. Suitable heat exchanger


20


may include for example plate-fin exchangers, spiral wound exchangers, and printed circuit exchangers, which all cool by indirect heat exchange. Nitrogen is a preferred refrigerant for closed-cycle refrigeration system


21


, which is a well-known means of cooling by indirect heat exchange. The term “indirect heat exchange,” as used in this description, means the bringing of two fluid streams into heat exchange relation without any physical contact or intermixing of the fluids with each other. The optimal coolant for closed-cycle cooling loop


21


and the optimal heat exchanger


20


can be determined by those having ordinary skill in the art taking into account the flow rate and compositions of fluids passing through heat exchanger


20


.




After exiting heat exchanger


20


, boil-off stream


11


is compressed by compressor


22


. The power requirements of compressor


22


will depend in part on the preselected pressure for liquefied product stream


29


. Compressor


22


boosts the pressure of boil-off stream


11


to a pressure above the preselected pressure of liquefied product stream


29


, preferably the pressure of boil-off stream


11


is boosted to more than about 100 psia (700 kPa) above the preselected pressure of liquefied product stream


29


, and more preferably between about 300 and about 600 pounds (2,070 to 4,140 kPa) above the preselected pressure of liquefied product stream


29


.




Compressor


22


is shown in

FIG. 1

as a single stage, which in most applications will be sufficient. It is understood, however, that in the practice of this invention a plurality of compressor stages or compressor units can be used (for example, three compression stages with two intercoolers). The last after-cooler is preferably positioned downstream from the last compression stage. In

FIG. 1

, only one after-cooler


23


is shown, preferably using ambient air or water as the cooling medium.




From after-cooler


23


, boil-off stream


12


is optionally passed to a nitrogen rejection unit


24


for removal of a predetermined amount of nitrogen via rejection stream


44


. The nitrogen removal can be carried out using any suitable nitrogen removal process of the kind that are well known in the art. For example, nitrogen may be removed by a cryogenic fractionation system, a molecular sieve system such as pressure swing adsorption, or a porous membrane system.




After exiting nitrogen rejection unit


24


, compressed boil-off stream


12


is passed through heat exchanger


20


for additional cooling. From heat exchanger


20


, boil-off stream


13


is passed through a second heat exchanger


25


, which is also cooled by closed-cycle cooling loop


21


. After passing through heat exchanger


25


, boil-off stream


14


is passed to an expansion means, such as Joule-Thomson valve


26


to further reduce the temperature of boil-off stream


14


. This isenthalpic reduction in pressure results in the flash evaporation of a gas fraction, liquefaction of the balance of the boil-off, and an overall reduction in temperature of both the boil-off fraction and the remaining liquid fraction in cooled boil-off stream


15


. To produce a high pressure liquefied natural gas product stream


29


from boil-off feed stream


10


in accordance with the practice of this invention, the temperature of cooled boil-off stream


15


is preferably above about −112° C. (−170° F.). Boil-off stream


15


is passed to phase separator


28


from which reliquefied boil-off stream


16


is withdrawn and passed to a temporary storage container


30


.




Also withdrawn from phase separator


28


is separated boil-off vapor stream


17


, which is rich in methane and, depending on the nitrogen content, if any, of boil-off feed stream


10


and depending on the amount, if any, of nitrogen removed by nitrogen rejection unit


24


, vapor stream


17


may also contain nitrogen. Vapor stream


17


may be used for any suitable purpose such as for pressurized fuel.




In accordance with the practice of this invention, the temperature of boil-off stream


14


can be controlled to regulate the amount of uncondensed vapor volume of vapor stream


17


to match fuel needs, such as, without limiting this invention, for powering the liquefaction process of the present invention and for other process fuel needs. The volume of vapor stream


17


will increase with increases in the temperature of boil-off stream


14


. In one embodiment, if the fuel requirements of the liquefaction process are low, the temperature of stream


14


can be lowered. The desired temperature of boil-off stream


14


and the volume of vapor stream


17


can be regulated by adjusting the temperature, or more preferably the volume, of refrigerant of closed-loop cooling cycle


21


entering heat exchanger


25


. Appropriate adjustments can be determined by those skilled in the art in light of the teachings of this description.




Liquefied product stream


29


from temporary storage container


30


can be combined with PLNG that produced the boil-off being liquefied by the process of

FIG. 1

(boil-off feed stream


10


). The liquefied product in container


30


has substantially the same temperature as the PLNG to which it is to be combined (the “to-be-combined PLNG”) (not shown in FIG.


1


). Preferably, such liquefied product has a temperature within 3 degrees Centigrade of the temperature of the to-be-combined PLNG. The desired preselected bubble point temperature of the liquefied product in container


30


can be obtained by performing at least one of the following steps:




(i) before, during, or after liquefaction of boil-off feed stream


10


, removing from boil-off feed stream


10


a predetermined amount of one or more components having a vapor pressure greater than the vapor pressure of methane (such as N


2


removal by nitrogen rejection unit


24


), and




(ii) before, during, or after liquefaction of boil-off feed stream


10


, adding one or more hydrocarbons having a molecular weight heavier than methane and having a vapor pressure less than the vapor pressure of methane to boil-off feed stream


10


(such as C


2+


hydrocarbons addition via additive stream


18


to reliquefied boil-off stream


16


).




The amount of the one or more components removed and the amount of the one or more additives added are controlled to obtain the preselected bubble point temperature of the PLNG. The amount of additives to be added or components to be removed can be determined by performing a chemical analysis, using for example an in-line chromatograph, of the composition of boil-off feed stream


10


. A conventional computer-assisted process simulator using well known equation-of-state analyses can be used to determine the amount of components, e.g., nitrogen, that should be rejected and/or the amount of additives, e.g., C


2+


hydrocarbons, that should be added to boil-off stream


10


to achieve the desired temperature at the pressure of product stream


29


. Temporary storage container


30


can be used to collect reliquefied boil-off


16


for analysis prior to passing it as stream


29


to the main PLNG storage container (not shown in FIG.


1


). The addition of additives and/or removal of components to/from boil-off stream


10


can be performed in the process of this invention either in a semi-batch or continuous mode. Appropriate temperature sensors are preferably installed in temporary storage container


30


or in phase separator


28


to help monitor the temperature of the PLNG being returned to the main PLNG storage container.




Although

FIG. 1

shows additives being introduced by flow stream


18


to reliquefied boil-off stream


16


, it should be understood that part or all of any additive addition may be at one or more other locations in the liquefaction process shown in

FIG. 1

, including addition of additives before start of reliquefaction of boil-off feed stream


10


.





FIG. 2

illustrates another embodiment of the invention. Boil-off feed stream


100


, containing nitrogen and hydrocarbons such as methane, is passed through regulator valve


353


to heat exchanger


102


where the cold of boil-off feed stream


100


is used to cool warmer boil-off stream


120


that is passed through heat exchanger


102


. From heat exchanger


102


warmed boil-off stream


110


is compressed by one or more compressor stages


103


and then cooled by one or more after-coolers


104


. Cooled boil-off stream


120


(which cooled boil-off stream


120


is nonetheless warmer than boil-off feed stream


100


) may optionally be passed through a nitrogen rejection unit (NRU)


105


for removal of a preselected amount of nitrogen through rejection line


125


. NRU


105


may be a molecular sieve (such as a pressure swing absorption or temperature swing process), membrane, distillation process, or any other suitable process that operates at non-cryogenic temperatures. NRU


105


may remove part or all of the nitrogen from cooled boil-off stream


120


. After NRU


105


, cooled boil-off is passed through heat exchangers


102


,


106


and


107


. Although heat exchangers


102


,


106


, and


107


are shown in

FIG. 2

as separate units, these heat exchangers may also be packaged together in one box with, for example, a side feed inlet. After passing through heat exchanger


107


, further cooled boil-off stream


140


is pressure expanded by expansion valve


108


. Expanded boil-off stream


150


is then passed to phase separator


109


. Removed component stream


170


withdrawn from separator


109


is enriched in nitrogen. Normally removed component stream


170


has no flow, except during startup (cool down) or during process upset conditions. Pressurized liquefied boil-off stream


160


withdrawn from the bottom of separator


109


is passed through heat exchanger


111


in which stream


160


is further cooled. Cooled liquefied boil-off stream


161


from heat exchanger


111


is passed through heat exchanger


112


for further cooling. Further cooled liquefied boil-off stream


165


is then passed to nitrogen fractionating column


114


. Removable component stream


180


is enriched in nitrogen and liquid bottoms stream


190


is substantially depleted of nitrogen. A partial volume


195


of liquid bottoms stream


190


is passed through heat exchanger


112


to provide refrigeration duty for heat exchanger


112


. The partial volume


195


of liquid bottoms stream


190


that was passed through heat exchanger


112


(stream


200


) as well as the remaining volume


196


of liquid bottoms stream


190


that was not passed through heat exchanger


112


are both passed to phase separator


115


. Phase separator


115


may also be an integral part of the nitrogen fractionating column


114


. A vapor overhead stream


210


is withdrawn from phase separator


115


and returned to nitrogen fractionating column


114


. Although heat exchangers


111


and


112


are shown in

FIG. 2

as separate units, these heat exchangers can be combined in one unit.




Heat exchanger


112


operates as a reboiler for incorporation into nitrogen fractionating column


114


and also provides the final cooling for cooled liquefied boil-off stream


161


before fractionating column


114


. The temperature of cooled liquefied boil-off stream


161


entering heat exchanger


112


can be controlled by having stream


160


or stream


211


bypass heat exchanger


111


. If part or all of stream


160


or stream


211


is bypassed around heat exchanger


111


, the feed temperature of stream


161


to heat exchanger


112


is warmer that it would otherwise be and more reboil duty can be generated in heat exchanger


112


than would otherwise be. Increasing the reboil duty of heat exchanger


112


can be used to produce more stripping vapor (vapor overhead stream


210


) from separator


115


, thereby removing more nitrogen from the liquid bottoms stream


190


. In addition, partial volume


195


of stream


190


directed through exchanger


112


is used to affect the amount of stripping vapor


210


generated. Minimizing the temperature of stream


165


, prior to expansion by expansion valve


113


, reduces the amount of methane in removable component stream


180


. Removable component stream


180


may be used as fuel in power-producing systems such as, without limiting this invention, gas turbines or pressurized steam generating heaters on a ship. From heat exchanger


112


stream


165


is passed through expansion valve


113


. Expanded stream


175


is then passed through nitrogen fractionating column


114


.




Bottom stream


220


from phase separator


115


is boosted in pressure by pump


116


and passed through heat exchangers


111


,


107


, and


106


to provide refrigeration duty to the heat exchangers. If the bubble point of liquid stream


230


needs to be further increased, additives such as C


2+


hydrocarbons can be added via additives stream


290


to obtain a desired bubble point temperature in stream


240


. Stream


240


is then expanded by a suitable expansion means


351


to the desired bubble point pressure and the resulting expanded stream is passed to surge tank


123


. Vapor stream


300


is preferably continuously withdrawn from surge tank


123


to assure that the liquid in surge tank


123


remains at a preselected bubble point temperature. PLNG stream


310


is typically returned via pump


124


to the pressurized liquid (e.g., PLNG) from which boil-off feed stream


100


is generated. Vapor stream


300


is recycled back into boil-off feed stream


100


. A steady vapor stream


300


flow rate is preferred during the operation of the reliquefaction process illustrated in FIG.


2


. Valve


122


in stream


300


is used to control the pressure in surge tank


123


. The flow rate of vapor stream


300


can be increased by reducing the flow rate of refrigerant stream


270


of refrigeration cycle


221


, and similarly the flow rate of vapor stream


300


can be decreased by increasing the flow rate of refrigerant stream


270


. The flow rate of additives stream


290


is preferably flow-controlled, with the amount being added to achieve a desired bubble point temperature depending upon the particular composition of liquid stream


230


.




The primary refrigeration for the liquefaction process for the embodiment illustrated in

FIG. 2

is provided by closed refrigeration cycle


221


. A cooled refrigerant stream


250


is passed through heat exchangers


107


,


106


, and


102


. Refrigerant stream


260


exiting heat exchanger


102


is pressurized by one or more compressor stages


121


and one or more after-coolers


119


. From after-cooler


119


, refrigerant stream


270


is passed back through heat exchangers


102


and


106


. Refrigerant stream


280


exiting heat exchanger


106


is passed through one or more turbo expanders


118


which cool the refrigerant. Without hereby limiting this invention, the refrigerant of refrigeration cycle


221


may comprise methane, ethane, propane, butane, pentane, carbon dioxide, and nitrogen, or mixtures thereof. Preferably, the closed-loop refrigeration system uses nitrogen as the predominant refrigerant.




Although not shown in the drawings, the equipment used in the embodiments illustrated in FIG.


1


and

FIG. 2

would include a plurality of sensors for detecting various conditions in the liquefaction plant such as temperature, pressure, flow rates, and compositions. A plurality of controllers such as servo-controlled valves and one or more computers for controlling the valves can be used in operation of the plant. A computer-assisted control system can be used to provide the desired bubble point temperature of the liquid boil-off stream (for example, stream


29


of FIG.


1


). The control system can respond to changes in plant conditions and can adjust various settings of the process equipment to eliminate departures from desired bubble point temperatures of the liquid product; the control system preferably therefore operates in a feedback mode.




EXAMPLE




A simulated mass and energy balance was carried out to illustrate the embodiment illustrated in

FIG. 2

, and the results are set forth in Table 1 below. The data were obtained using a commercially available process simulation program called HYSYS (available from Hyprotech Ltd. of Calgary, Canada); however, other commercially available process simulation programs, which are familiar to those of ordinary skill in the art, can be used to develop the data. The data presented in Table 1 are offered to provide a better understanding of the embodiment shown in

FIG. 2

, but the invention is not to be construed as limited thereto. The temperatures and flow rates are not to be considered as limitations upon the invention. The invention can have many variations in temperatures and flow rates in view of the teachings herein.




While this invention has been described primarily in relation to liquefied natural gas, the invention is not limited thereto, and may be useful with any liquid methane-rich gas. A person skilled in the art, particularly one having the benefit of the teachings of this specification, will recognize many modifications and variations to the specific processes disclosed above. For example, a variety of temperatures and pressures may be used in accordance with the invention, depending on the overall design of the system and the composition of the feed vapor. Also, the feed vapor cooling train may be supplemented or reconfigured depending on the overall design requirements to achieve optimum and efficient heat exchange requirements. As discussed above, the specifically disclosed embodiments and examples should not be used to limit or restrict the scope of the invention, which is to be determined by the claims below and their equivalents.














TABLE 1













Composition























Pressure




Pressure




Temp




Temp




Flow




Flow




ethane




methane




nitrogen






Stream




Phase




psia




kPa




° F.




° C.




lbmole/hr




kgmole/hr




mole %




mole %




mole %
























100




Vapor




410




2898




−100




−73




1098




498.3




0.70




94.8




4.6






110




Vapor




390




2691




55.7




13.5




1153




523.2




0.64




95.0




4.4






120




Vapor




543




3747




80.0




27.0




1153




532.2




0.64




95.0




4.4






140




Liquid




530




3657




−220




−139.7




1153




532.2




0.64




95.0




4.4






150




Liquid




500




3450




−219.9




−139.6




1153




532.2




0.64




95.0




4.4






160




Liquid




500




3450




−219.9




−139.6




1153




532.2




0.64




95.0




4.4






170




Vapor




500




3450




−219.9




−139.6




0




0





















165




Liquid




490




3381




−252




−157.4




1153




532.2




0.64




95.0




4.4






175




2 phase




18




124.2




−264.1




−164.2




1153




532.2




0.64




95.0




4.4






180




Vapor




17




117.3




−265.9




−165.2




128.0




58.1









61.2




38.8






190




Liquid




18.0




124.2




−255.3




−159.3




1075.0




487.8




0.69




99.2




0.10






200




2 phase




18.0




124.2




−254.4




−158.8




1075.0




487.8




0.69




99.2




0.10






210




Vapor




18.0




124.2




−254.4




−158.8




49.6




22.5









98.9




1.1






220




Liquid




470




3243




−228.0




−144.1




1025.0




465.1




0.72




99.2




0.05






230




Liquid




462




3188




−139.1




−94.7




1025.0




465.1




0.72




99.2




0.05






240




Liquid




462




3188




−138.2




−94.2




1036.0




470.1




1.75




98.2




0.05






250




Vapor




220




1518




−219.7




−139.5




9033.0




4099.0









0




1.0






260




Vapor




207




1428




55.7




13.5




9033.0




4099.0









0




1.0






270




Vapor




725




5003




80.0




27.0




9033.0




4099.0









0




1.0






280




Vapor




715




4934




−135.0




−92.4




9033.0




4099.0









0




1.0






290




Vapor




465




3209




−140.0




−95.2




10.98




4.98




99.50




0.5











300




Vapor




410




2829




−142.9




−96.8




54.8




24.9




0.25




99.61




0.14






310




Liquid




415




2864




−142.7




−96.7




981.2




445.3




1.86




98.1




0.04













Claims
  • 1. A method of converting a boil-off stream comprising methane to a liquid having a preselected bubble point temperature, comprising the steps of:(a) pressurizing the boil-off stream; (b) cooling the pressurized boil-off stream of step (a); (c) expanding the cooled, pressurized boil-off stream of step (b), thereby producing pressurized liquid; and (d) obtaining the preselected bubble point temperature of the pressurized liquid by performing at least one of the following steps: i. before, during, or after one or more of steps (a) to (c), removing from the boil-off stream a first predetermined amount of one or more components having a vapor pressure greater than the vapor pressure of methane, and ii. before, during, or after one or more of steps (a) to (c), adding to the boil-off stream a second predetermined amount of one or more additives having a molecular weight heavier than the molecular weight of methane and having a vapor pressure less than the vapor pressure of methane,  wherein the first predetermined amount of the one or more components removed and the second predetermined amount of the one or more additives added are controlled to obtain the preselected bubble point temperature of the pressurized liquid.
  • 2. The method of claim 1 wherein the one or more components removed from the boil-off stream comprise nitrogen.
  • 3. The method of claim 1 wherein the one or more additives added to the boil-off stream comprise one or more C2+ hydrocarbons.
  • 4. The method of claim 1 further comprising combining the pressurized liquid having the preselected bubble point temperature with a second pressurized liquid having substantially the same bubble point temperature.
  • 5. The method of claim 4 wherein the second pressurized liquid produced the boil-off stream being liquefied.
  • 6. The method of claim 1 further comprising before step (d), determining an amount of a first component of said one or more components to be removed from the boil-off stream, the first component having a vapor pressure greater than the vapor pressure of methane, and determining an amount of a first additive of said one or more additives to be added to the boil-off stream, the first additive having a molecular weight heavier than the molecular weight of methane and having a vapor pressure less than the vapor pressure of methane, both of said determinations being performed by determining the composition of the boil-off stream and performing an equation of state analysis to determine a pressurized liquid composition needed to obtain the preselected bubble point temperature in said pressurized liquid at a preselected pressure.
  • 7. The method of claim 1 further comprising before step (d), determining the first predetermined amount of the one or more components to be removed from the boil-off stream, and determining the second predetermined amount of the one or more additives to be added to the boil-off stream, both of said determinations being performed by determining the composition of the boil-off stream and performing an equation of state analysis to determine a pressurized liquid composition needed to obtain the preselected bubble point temperature in said pressurized liquid at a preselected pressure.
  • 8. A method of converting a boil-off stream comprising methane to a liquid having a preselected bubble point temperature, comprising the steps of:(a) pressurizing the boil-off stream; (b) cooling the pressurized boil-off stream of step (a); (c) expanding the cooled, pressurized boil-off stream of step (b), thereby producing pressurized liquid; and (d) obtaining the preselected bubble point temperature of the pressurized liquid by performing at least one of the following steps: i. before, during, or after one or more of steps (a) to (c), removing from the boil-off stream a first predetermined amount of nitrogen, and ii. before, during, or after one or more of steps (a) to (c), adding to the boil-off stream a second predetermined amount of one or more C2+ hydrocarbons,  wherein the first predetermined amount of the nitrogen removed and the second predetermined amount of the one or more C2+ hydrocarbons added are controlled to obtain the preselected bubble point temperature of the pressurized liquid.
  • 9. A method of converting a boil-off stream comprising methane to a liquid having a preselected bubble point temperature, comprising the steps of:(a) pressurizing the boil-off stream; (b) cooling the pressurized boil-off stream of step (a); (c) expanding the cooled, pressurized boil-off stream of step (b), thereby producing pressurized liquid; and (d) obtaining the preselected bubble point temperature of the pressurized liquid by performing at least one of the following steps: i. before, during, or after one or more of steps (a) to (c), removing from the boil-off stream a first predetermined amount of nitrogen, and ii. before, during, or after one or more of steps (a) to (c), adding to the boil-off stream a second predetermined amount of one or more C2+ hydrocarbons,  wherein the first predetermined amount of the nitrogen removed and the second predetermined amount of the one or more C2+ hydrocarbons added are controlled to obtain the preselected bubble point temperature of the pressurized liquid, and further comprising before step (d), determining the first predetermined amount of the nitrogen to be removed from the boil-off stream, and determining the second predetermined amount of the one or more C2+ hydrocarbons to be added to the boil-off stream, both of said determinations being performed by determining the composition of the boil-off stream and performing an equation of state analysis to determine a pressurized liquid composition needed to obtain the preselected bubble point temperature in said pressurized liquid at a preselected pressure.
Parent Case Info

This application claims the benefit of U.S. Provisional Application No. 60/368,325, filed Mar. 28, 2002.

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Number Name Date Kind
3735600 Dowdell et al. May 1973 A
3857245 Jones Dec 1974 A
3857251 Alleaume Dec 1974 A
3874185 Etzbach Apr 1975 A
3885394 Witt et al. May 1975 A
3919852 Jones Nov 1975 A
3919853 Rojey Nov 1975 A
4187689 Selcukoglu et al. Feb 1980 A
4320303 Ooka et al. Mar 1982 A
4689962 Lofredo Sep 1987 A
4727723 Durr Mar 1988 A
4750333 Husain et al. Jun 1988 A
4840652 Simon et al. Jun 1989 A
4843829 Stuber et al. Jul 1989 A
4846862 Cook Jul 1989 A
5006138 Hewitt Apr 1991 A
5076822 Hewitt Dec 1991 A
5389242 Lermite et al. Feb 1995 A
5402645 Johnson et al. Apr 1995 A
5950453 Bowen et al. Sep 1999 A
5956971 Cole et al. Sep 1999 A
6023942 Thomas et al. Feb 2000 A
6192705 Kimble, III Feb 2001 B1
6250244 Dubar et al. Jun 2001 B1
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Number Date Country
1132698 Sep 2001 EP
2333149 Jul 1999 GB
WO 9000589 Jan 1990 WO
Provisional Applications (1)
Number Date Country
60/368325 Mar 2002 US