JP2008503609A5 - - Google Patents
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- JP2008503609A5 JP2008503609A5 JP2007516592A JP2007516592A JP2008503609A5 JP 2008503609 A5 JP2008503609 A5 JP 2008503609A5 JP 2007516592 A JP2007516592 A JP 2007516592A JP 2007516592 A JP2007516592 A JP 2007516592A JP 2008503609 A5 JP2008503609 A5 JP 2008503609A5
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- processing unit
- unit module
- liquefaction plant
- processing
- lng liquefaction
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- 239000003949 liquefied natural gas Substances 0.000 claims 77
- 239000003507 refrigerant Substances 0.000 claims 29
- 238000010276 construction Methods 0.000 claims 12
- 238000004519 manufacturing process Methods 0.000 claims 8
- 239000000463 material Substances 0.000 claims 5
- 239000007789 gas Substances 0.000 claims 4
- IJGRMHOSHXDMSA-UHFFFAOYSA-N nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 claims 4
- 238000001816 cooling Methods 0.000 claims 3
- 238000000034 method Methods 0.000 claims 3
- 239000002253 acid Substances 0.000 claims 2
- 238000006297 dehydration reaction Methods 0.000 claims 2
- 239000012530 fluid Substances 0.000 claims 2
- 239000001307 helium Substances 0.000 claims 2
- 229910052734 helium Inorganic materials 0.000 claims 2
- SWQJXJOGLNCZEY-UHFFFAOYSA-N helium(0) Chemical compound [He] SWQJXJOGLNCZEY-UHFFFAOYSA-N 0.000 claims 2
- 229910052757 nitrogen Inorganic materials 0.000 claims 2
- 238000011084 recovery Methods 0.000 claims 2
- 238000004891 communication Methods 0.000 claims 1
- 238000005194 fractionation Methods 0.000 claims 1
- 239000003345 natural gas Substances 0.000 claims 1
Claims (77)
A) 該LNG液化プラント内に含まれる、複数の処理ユニットモジュール型を識別する工程、ここで該複数の処理ユニットモジュール型は、少なくとも第一の処理ユニットモジュール型と、第二の処理ユニットモジュール型とを含み;
B) 該第一の処理ユニットモジュール型の第一処理ユニットモジュールに関する第一の最大処理効率および該第二の処理ユニットモジュール型の第二処理ユニットモジュールに関する第二の最大処理効率を決定する工程;および
C) 該LNG液化プラントを設計する工程を含み、該LNG液化プラントの設計が、該第一の最大処理効率を実質的に満足するサイズを持つ、1またはそれ以上の第一の処理ユニットモジュール、および該第二の最大処理効率を実質的に満足するサイズを持つ、1またはそれ以上の第二の処理ユニットモジュールを含むことを特徴とする、上記方法。 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) 該LNG液化プラントの既存の構成を準備する工程、ここで該LNG液化プラントは、複数の処理ユニットモジュール型を含み;
B) 付随的な最大供給材料処理能力を必要とする、第一の処理ユニットモジュール型を決定して、該既存のプラント最大供給材料処理能力を高める工程;
C) 該第一の処理ユニットモジュール型の、第一の処理ユニットモジュールの最大処理効率を決定する工程;および
D) 拡張されたLNG液化プラントを設計する工程を含み、該設計が、該最大処理効率を実質的に満足するサイズを持つ、1またはそれ以上の第一の処理ユニットモジュールの付加を含むことを特徴とする、上記方法。 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) 第一のプラント供給材料処理速度を測定する工程、
B) 該第一のプラント供給材料処理速度を満たすのに必要な、各処理ユニットモジュール型の処理ユニットモジュール数を決定する工程、
C) 少なくとも該工程B)において決定された数の、該第一プラント供給材料処理速度を満たすのに必要な、各処理ユニットモジュール型の各処理ユニットモジュールを稼動状態に就かせる工程、および
D) LNGを生産する工程、を含むことを特徴とする、上記方法。 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) 該複数の処理ユニットモジュール型に含まれる、各処理ユニットモジュール型に対して、少なくとも一つの原処理ユニットモジュールを設ける工程、ここで1またはそれ以上の該原処理ユニットモジュールは、夫々の実質的に最大の処理効率をとるようなサイズで形成され、結果的に第一段階のLNG液化プラントを与え、
B) 該第一段階のLNG液化プラントに含まれる、1またはそれ以上の処理ユニットモジュール型に対して、1またはそれ以上の追加の処理ユニットモジュールを設ける工程、ここで該追加の処理ユニットモジュールは、該処理ユニットモジュール型内で、該原処理ユニットモジュールと一体化され、結果として第二段階のLNG液化プラントを与え、および
C) 該第二段階のLNG液化プラントから、LNGを製造する工程、を含むことを特徴とする、上記方法。 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) 複数の製品サイズを持つ、処理ユニットモジュール型を含むLNG液化プラントを準備する工程、ここで該LNG液化プラントは、第一のプラント最大供給材料処理能力を有し;
B) 該製品サイズを持つ、処理ユニットモジュール型の少なくとも一つであるが、その全てよりも少ないものの、該最大供給材料処理能力を拡張して、該第一のプラント最大供給材料処理能力の10%以上である、第二のプラント最大供給材料処理能力を達成する工程、ここで該拡張は、少なくとも1つの追加の処理ユニットモジュールを追加することを含み;および
C) 該拡張段階(B)を開始した後に、該LNG液化プラント内でLNGを製造する工程、を含むことを特徴とする、上記方法。 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) 該複数の処理ユニットモジュール型に含まれる、各処理ユニットモジュール型に対して、少なくとも一つの原処理ユニットモジュールを設け、結果的に第一段階のLNG液化プラントを与える工程;
B) 該第一段階のLNG液化プラントから第一のLNGを製造する工程;
C) 該第一段階のLNG液化プラントに含まれる、1またはそれ以上の処理ユニットモジュール型に対して、1またはそれ以上の追加の処理ユニットモジュールを構築し、一方で該製造段階(B)の少なくとも1部を完成させる工程;
D) 該1またはそれ以上の追加の処理ユニットモジュールを作動状態に置く工程、ここで該追加の処理ユニットモジュールは、該処理ユニットモジュール型内で、該原処理ユニットモジュールと一体化され、結果として第二段階のLNG液化プラントを与え;および
E) 該第二段階のLNG液化プラントから第二のLNGを製造する工程を含むことを特徴とする、上記方法。 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) 複数の処理ユニットモジュール型を含むLNG液化プラントを準備する工程、ここで該LNG液化プラントは、少なくとも一つの第一の冷媒回路を持ち、該第一の冷媒回路は、少なくとも一つの第一の冷媒圧縮機サービス型を含み、該第一の冷媒圧縮機サービス型は、並列状態にある、1またはそれ以上の第一の原冷媒圧縮機で構成され、該LNG液化プラントは、プラント最大供給材料処理能力を持ち;
B) 少なくとも一つの追加の第一冷媒圧縮機を、該第一の冷媒圧縮機サービス型に付加することによって、該LNG液化プラントの該プラント最大供給材料処理能力を拡張させる工程、ここで該追加の第一冷媒圧縮機は、該第一の冷媒圧縮機サービス型内で、1またはそれ以上の該原第一冷媒圧縮機と一体化されており;および
C) 該拡張工程(B)の開始後に、該LNG液化プラント内でLNGを製造する工程;を含むことを特徴とする、上記方法。 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) 該複数の処理ユニットモジュール型に含まれる、各処理ユニットモジュール型に対して、少なくとも一つの原処理ユニットモジュールを設けて、第一段階のLNG液化プラントを与える工程;
B) 該複数の処理ユニットモジュール型に含まれる、各処理ユニットモジュール型に対して、少なくとも一つの第二の処理ユニットモジュールを設けて、第二段階のLNG液化プラントを与える工程;
C) 2またはそれ以上の各処理ユニットモジュール型に対して、1またはそれ以上の該原処理ユニットモジュールと、1またはそれ以上の該第二の処理ユニットモジュールとを一体化する工程;および
D) 該一体化工程(C)を開始した後に、該LNG液化プラントからLNGを製造する工程;を含むことを特徴とする、上記方法。 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.
F) 該第二のプラント供給材料処理速度を満たすのに必要とされる、各処理ユニットモジュール型の、処理ユニットモジュールの数を決定する工程;および
G) 少なくとも該工程(F)において決定された数の、該第二プラント供給材料処理速度を満たすのに必要な、各処理ユニットモジュール型の各処理ユニットモジュールを、稼動状態に就かせる工程、を更に含む、請求項4記載の方法。 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:
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US58074604P | 2004-06-18 | 2004-06-18 | |
PCT/US2005/020674 WO2006009646A2 (en) | 2004-06-18 | 2005-06-10 | Scalable capacity liquefied natural gas plant |
Publications (2)
Publication Number | Publication Date |
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JP2008503609A JP2008503609A (en) | 2008-02-07 |
JP2008503609A5 true JP2008503609A5 (en) | 2008-07-24 |
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Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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JP2007516592A Pending JP2008503609A (en) | 2004-06-18 | 2005-06-10 | A liquefied natural gas plant with appreciable capacity |
Country Status (11)
Country | Link |
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US (1) | US20070193303A1 (en) |
EP (1) | EP1782008A4 (en) |
JP (1) | JP2008503609A (en) |
KR (1) | KR101244759B1 (en) |
CN (1) | CN101023308B (en) |
AU (1) | AU2005264908C1 (en) |
BR (1) | BRPI0512212A (en) |
CA (1) | CA2570835C (en) |
MX (1) | MXPA06014854A (en) |
NO (1) | NO20070307L (en) |
WO (1) | WO2006009646A2 (en) |
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