JP2008503609A5 - - Google Patents

Claims (77)

  A method for producing liquefied natural gas using an LNG liquefaction plant, the LNG liquefaction plant comprising a plurality of processing unit module types, wherein the plurality of processing unit module types is at least one or more first. A first processing unit module type including a processing unit module; and a second processing unit module type including two or more integrated second processing unit modules; and at least one first processing unit The module and at least one of the second processing unit modules are each sized to obtain substantially maximum processing efficiency, and the LNG liquefaction plant comprises two or more integrated processes A unit module type, wherein the method includes the step of producing liquefied natural gas from the LNG liquefaction plant. Wherein the manufacturing method of the liquefied natural gas. LNG liquefaction plant design method,
A) Identifying a plurality of processing unit module types included in the LNG liquefaction plant, wherein the plurality of processing unit module types are at least a first processing unit module type and a second processing unit module type Including:
B) determining a first maximum processing efficiency for the first processing unit module of the first processing unit module type and a second maximum processing efficiency for the second processing unit module of the second processing unit module type; and
C) one or more first processing unit modules comprising a step of designing the LNG liquefaction plant, the LNG liquefaction plant design having a size that substantially satisfies the first maximum processing efficiency; And one or more second processing unit modules having a size that substantially satisfies the second maximum processing efficiency. A method for designing an expanded LNG liquefaction plant capacity that has the maximum feed capacity of existing plants,
A) preparing an existing configuration of the LNG liquefaction plant, wherein the LNG liquefaction plant includes a plurality of processing unit module types;
B) determining the first processing unit module type that requires ancillary maximum feed throughput and increasing the existing plant maximum feed throughput;
C) determining the maximum processing efficiency of the first processing unit module of the first processing unit module type; and
D) designing an expanded LNG liquefaction plant, the design comprising adding one or more first processing unit modules having a size that substantially satisfies the maximum processing efficiency. A method as described above, characterized. A plurality of processing unit module types, wherein the plurality of processing unit module types are composed of one or more first processing unit modules and a first processing unit module type and two or more integrated At least a second processing unit module type comprising a second processing unit module, wherein at least one first processing unit module and at least one second processing unit module are each substantially Is a method of operating an LNG liquefaction plant, which is formed in a size that takes the maximum processing capacity,
A) measuring the first plant feed rate,
B) determining the number of processing unit modules of each processing unit module type required to satisfy the first plant feedstock processing rate;
C) putting each processing unit module of each processing unit module type into operation, as required to meet at least the number of steps B) determined in the first plant feedstock processing rate; and
D) A process as described above, comprising the step of producing LNG. A method for producing LNG using an LNG liquefaction plant, wherein the LNG liquefaction plant is constituted by a plurality of processing unit module types, each of the plurality of processing unit module types being one or more processing unit modules. The method comprising:
A) providing at least one original processing unit module for each processing unit module type included in the plurality of processing unit module types, wherein one or more original processing unit modules are each substantive Is formed to a size that maximizes the processing efficiency, resulting in a first-stage LNG liquefaction plant,
B) providing one or more additional processing unit modules for one or more processing unit module types included in the first stage LNG liquefaction plant, wherein the additional processing unit modules are Integrated with the raw processing unit module within the processing unit module mold, resulting in a second stage LNG liquefaction plant, and
C) producing the LNG from the second stage LNG liquefaction plant. A method for producing liquefied natural gas, comprising:
A) preparing an LNG liquefaction plant having a plurality of product sizes and including a processing unit module type, wherein the LNG liquefaction plant has a first plant maximum feed capacity;
B) At least one of the processing unit module types having the product size, but less than all of them, expands the maximum feedstock processing capacity to 10% of the first plant maximum feedstock processing capacity. Achieving a second plant maximum feedstock throughput that is greater than or equal to% , wherein the expansion includes adding at least one additional processing unit module ; and
C) producing the LNG in the LNG liquefaction plant after starting the expansion step (B). A method for producing liquefied natural gas using an LNG liquefaction plant, wherein the LNG liquefaction plant is composed of a plurality of processing unit module types, each of the plurality of processing unit module types being one or more processing unit modules And the method comprises:
A) providing at least one raw processing unit module for each processing unit module type included in the plurality of processing unit module types, resulting in a first stage LNG liquefaction plant;
B) producing a first LNG from the first stage LNG liquefaction plant;
C) Build one or more additional processing unit modules for one or more processing unit module types included in the first stage LNG liquefaction plant, while the manufacturing stage (B) Completing at least one part;
D) placing the one or more additional processing unit modules in operation, wherein the additional processing unit modules are integrated with the original processing unit module within the processing unit module mold, resulting in Giving a second stage LNG liquefaction plant; and
E) The above method, comprising the step of producing a second LNG from the second stage LNG liquefaction plant. A method for producing liquefied natural gas comprising the following steps:
A) preparing an LNG liquefaction plant including a plurality of processing unit module types, wherein the LNG liquefaction plant has at least one first refrigerant circuit, and the first refrigerant circuit is at least one first refrigerant circuit. The first refrigerant compressor service type is composed of one or more first raw refrigerant compressors in parallel, and the LNG liquefaction plant has a maximum plant supply. Has material processing capability;
B) Expanding the plant maximum feed capacity of the LNG liquefaction plant by adding at least one additional first refrigerant compressor to the first refrigerant compressor service type, wherein the additional The first refrigerant compressor is integrated with one or more of the original first refrigerant compressors in the first refrigerant compressor service type; and
C) producing the LNG in the LNG liquefaction plant after the start of the expansion step (B). A method for producing liquefied natural gas using an LNG liquefaction plant, wherein the LNG liquefaction plant includes a plurality of processing unit module types, and each of the plurality of processing unit module types includes one or more processing unit modules. Including the following steps:
A) providing at least one raw processing unit module for each processing unit module type included in the plurality of processing unit module types to provide a first stage LNG liquefaction plant;
B) Providing a second stage LNG liquefaction plant by providing at least one second processing unit module for each processing unit module type included in the plurality of processing unit module types;
C) integrating two or more of each processing unit module type with one or more of the original processing unit modules and one or more of the second processing unit modules; and
And D) producing the LNG from the LNG liquefaction plant after the integration step (C) is started. The method according to any one of claims 1 to 9 , wherein the substantially maximum processing efficiency is within 25% of an actual maximum processing efficiency. 11. The method of claim 10 , wherein the substantially maximum processing efficiency is within 10% of the actual maximum processing efficiency. Outermost sized processing efficiency, per unit of the processing unit module capacity, to minimize the life cycle cost of the total process unit module, for each processing unit module type is the ability size of the processing unit module, according to claim 11, wherein the method of. 12. The method of claim 11 , wherein the LNG liquefaction plant further comprises a third processing unit module type comprised of one or more third processing unit modules. 12. The method of claim 11 , wherein the maximum feed capacity of the second processing unit module type is at least equal to the maximum feed capacity of the first processing unit module type. The first and second processing unit module types have first and second construction costs per unit of maximum feedstock throughput, and the first construction cost per unit of maximum feedstock throughput is 15. The method of claim 14 , wherein the second construction cost per unit of the maximum feedstock throughput is exceeded. 14. The method of claim 13 , wherein the LNG liquefaction plant comprises at least one of the processing unit module types in parallel and having a plurality of substantially equal sized processing unit modules. 17. The method of claim 16 , wherein the LNG liquefaction plant includes at least one of the processing unit module types having a processing unit module in parallel and formed in a plurality of substantially equal shapes. 14. The method of claim 13 , wherein the third processing unit module type comprises a third processing unit module that is sized to provide substantially maximum processing efficiency. The first processing unit module is composed of a first type of apparatus, the second processing unit module is composed of a second processing apparatus type, and the third processing unit module is a third type. 14. The method according to claim 13 , wherein the method comprises: 20. The method of claim 19 , wherein at least some of the device types are formed with substantially equal shapes. 21. The method of claim 20 , wherein at least some of the device types are formed with substantially equal sizes. 14. The method of claim 13 , wherein the maximum feed capacity of the first processing unit module type differs from the capacity of the second processing unit module type by more than 10%. 23. The method of claim 22 , wherein the second processing unit module type has a maximum feed capacity that is less than 85% of the maximum feed capacity of the first processing unit module type. 23. The method of claim 22 , wherein the first processing unit module type has a maximum feed capacity that is less than 85% of the maximum feed capacity of the second processing unit module type. 24. The method of claim 22 , wherein at least two of the processing unit module types have a maximum feed capacity that is less than 85% of the maximum feed capacity of the first processing unit module type. 23. The method of claim 22 , wherein at least two of the processing unit module types have a maximum feed capacity that is less than 85% of the maximum feed capacity of the second processing unit module type. 14. The method of claim 13 , wherein the LNG liquefaction plant comprises a liquefaction unit, the liquefaction unit being composed of one or more cryogenic heat exchangers and a plurality of similar function refrigerant compressors. 28. The method of claim 27 , wherein at least two of the plurality of compressors are arranged in parallel. 29. The method of claim 28 , wherein the liquefaction unit comprises a plurality of cryogenic heat exchangers having a similar role, the cryogenic heat exchangers being arranged in parallel. 30. The method of claim 29 , wherein each of the plurality of compressors is in fluid communication with two or more cryogenic heat exchangers. 32. The method of claim 30 , wherein the liquefaction unit is formed in a shape such that each of the plurality of compressors can be placed in fluid connection with any of the cryogenic heat exchangers. 32. The method of claim 31 , wherein the plurality of cryogenic heat exchangers includes one or more modular heat exchangers. 35. The method of claim 32 , wherein the plurality of cryogenic heat exchangers include one or more plate-fin heat exchangers. 35. The method of claim 32 , wherein the plurality of cryogenic heat exchangers include one or more spiral heat exchangers. The LNG liquefaction plant has a maximum feed processing capacity and a plant minimum feed processing capacity plant, said plant minimum feed processing capacity is 75% or less of said plant maximum feed processing capacity, according to claim 13, wherein the method of. 36. The method of claim 35 , wherein the plant minimum feed capacity is 55% or less of the plant maximum feed capacity. 14. The method of claim 13 , wherein at least one of the processing unit module types comprises a variable speed compressor, a variable speed expander, or a combination thereof. The method of claim 6 , wherein the plant maximum feedstock throughput exceeds 4 million tonnes per year. The method according to any one of claims 1 to 9, wherein the LNG liquefaction plant comprises three or more integrated processing unit module types. The method of any one of claims 2-9, wherein the LNG liquefaction plant design comprises two or more integrated processing unit module types. And E) determining a second plant feedstock processing rate;
F) determining the number of processing unit modules of each processing unit module type required to meet the second plant feedstock processing rate; and
G) placing each processing unit module of each processing unit module type, which is required to satisfy at least the number of the second plant feed material processing rates determined in step (F), into operation; The method of claim 4 , further comprising: The processing unit module type having the product size is an acid gas removal contactor unit, a dehydration unit, a deethanization unit, a cryogenic heat exchanger unit, a refrigerant compressor unit, a nitrogen exclusion unit, a liquefaction unit, a helium recovery unit, 7. The method of claim 6 , wherein the method is selected from and combinations thereof. At least one first processing unit module type, and two or more integrated second units, wherein the processing unit module type having the product size is composed of one or more first processing unit modules. A second processing unit module type comprised of processing unit modules, wherein at least one of the first processing unit modules and at least one of the second processing unit modules are each substantially maximum 43. The method of claim 42 , wherein the method is sized to achieve a processing efficiency of: The method according to claim 7 , wherein the operation step D is operated, and the first LNG is produced in the step B. The method according to claim 7 , wherein the operation step D is at least partially operated, and the first LNG is produced in the step B. 8. The method of claim 7 , wherein the actuating step D is at least partially in operation and the step B does not produce a first LNG. 48. The method of claim 46 , wherein the operating step D is at least partially in operation and the first LNG is not produced in the step B for less than 10 days. 8. The method of claim 7 , wherein at least one of the additional processing unit modules is sized to provide each substantially maximum processing efficiency. 49. The method of claim 48 , wherein the original and additional processing unit modules are formed in substantially equal shapes. 50. The method of claim 49 , wherein the raw processing unit module is configured with a raw device type and the additional processing unit module is configured with an additional processing device type. 9. The method of claim 8 , wherein the at least one first raw refrigerant compressor and the at least one additional first refrigerant compressor are of substantially equal size. 52. The method of claim 51 , wherein the at least one first raw refrigerant compressor and the at least one additional first refrigerant compressor are substantially equal and mechanically formed. 53. The method of claim 52 , wherein the first raw refrigerant compressor comprises a plurality of first refrigerant compressors, and the plurality of first raw refrigerant compressors has a maximum overall throughput. 54. The method of claim 53 , wherein the maximum overall throughput is less than that of the largest commercially available compressor. 54. The method of claim 53 , wherein each of the plurality of first raw refrigerant compressors has a processing capacity less than that of the largest commercially available compressor. 54. The method of claim 53 , wherein the first raw refrigerant compressor comprises an electrically driven compressor. 53. The method of claim 52 , wherein the first raw refrigerant compressor comprises a gas turbine driven compressor. The first refrigerant circuit further includes one or more plate-fin heat exchangers, wherein the plate-fin heat exchangers pass through natural heat exchange with the refrigerant compressed by the first refrigerant compressor. 53. The method of claim 52 , wherein the method is suitable for cooling a gas stream. 59. The method of claim 58 , wherein the one or more plate-fin heat exchangers comprise a plurality of plate-fin heat exchangers arranged in a cooling box. The first refrigerant circuit further includes one or more spiral heat exchangers through which the natural gas stream passes through heat exchange with the refrigerant compressed by the first refrigerant compressor. 53. The method of claim 52 , wherein the method is suitable for cooling. The processing unit module type is composed of one or more first processing unit modules, a first processing unit module type and two or more integrated second processing unit modules. , At least a second processing unit module type, wherein at least one of the first processing unit modules and at least one of the second processing unit modules has their respective substantially maximum processing efficiency. 9. The method of claim 8 , wherein the method is made of any size. The integration step C includes integrating one or more original processing unit modules and one or more second processing unit modules of each of three or more processing unit module types. 10. The method of claim 9 , comprising. The integration step C includes integrating one or more original processing unit modules and one or more second processing unit modules of each of four or more processing unit module types. 64. The method of claim 62 , comprising. The integration step C includes the step of integrating all the one or more original processing unit modules and the one or more second processing unit modules of the plurality of processing unit module types. 64. The method of claim 63 . The method of claim 9 , wherein the second processing unit modules are sized such that each has a substantially maximum processing efficiency. 66. The method of claim 65 , wherein the original and second processing unit modules of the same processing unit module type are formed in substantially equal shapes. 68. The method of claim 66 , wherein the raw processing unit module is configured with an original apparatus type and the second processing unit module is configured with a second processing apparatus type.   One or more processing unit module types having a product size having a high construction cost and one or more processing unit module types having a product size having a low construction cost, and having at least one of the low construction costs, A processing unit module type with a product size has a maximum feed material processing capacity of at least 110% of the maximum feed material processing capacity of a processing unit module type with a product size of at least one of the high construction costs LNG liquefaction plant. The processing unit module type with the product size of the high construction cost is not less than 1.25 times the total construction cost per unit of the maximum feed material processing capacity of the processing unit module type with the product size of the low construction cost, 69. The LNG liquefaction plant of claim 68 , having a total construction cost per unit of maximum feedstock throughput. 69. The LNG liquefaction plant of claim 68 , wherein the low build cost, product size processing unit module type is selected from an acid gas removal unit, a dehydration unit, a fractionation unit, a nitrogen exclusion unit, and a helium recovery unit. 69. The LNG liquefaction plant of claim 68 , wherein the high construction cost, processing unit module type with product size is selected from an introduction equipment unit, a refrigerant compressor unit, a cryogenic heat exchanger unit, and a liquefaction unit. A first processing unit module type having the product size, wherein the processing unit module type is composed of one or more first processing unit modules, and two or more integrated second processing unit modules; At least a second processing unit module type, wherein at least one of the first processing unit modules and at least one of the second processing unit modules are each substantially maximum processing. 69. The LNG liquefaction plant of claim 68 , sized for efficiency.   A plurality of processing unit module types and two or more integrated processing unit module types, wherein the plurality of processing unit module types comprise one or more first processing unit modules Comprising at least one second processing unit module type comprised of a first processing unit module type and two or more integrated second processing unit modules. An LNG liquefaction plant, wherein the first processing unit module and the at least one second processing unit module are each sized to obtain a substantially maximum processing efficiency. 10. A method according to any one of the preceding claims, wherein the LNG liquefaction plant comprises one or more internally integrated processing unit modules. 74. An LNG liquefaction plant according to claim 68 or 73 , wherein the LNG liquefaction plant comprises one or more internally integrated processing unit modules. The method according to any one of claims 1 to 9 , wherein the LNG liquefaction plant comprises two or more processing unit modules integrated in parallel . 74. An LNG liquefaction plant according to claim 68 or 73 , wherein the LNG liquefaction plant comprises two or more parallel integrated processing unit modules.