A refrigerant circuit includes a first compression stage for compressing a mixed refrigerant gas, the first compression stage including at least a first compressor body and a second parallel compressor body, each compressor body including a suction inlet and an outlet, a first distribution means for
A refrigerant circuit includes a first compression stage for compressing a mixed refrigerant gas, the first compression stage including at least a first compressor body and a second parallel compressor body, each compressor body including a suction inlet and an outlet, a first distribution means for splitting the flow of refrigerant gas to the first stage of compression across the at least two parallel compressor bodies, such that a first stream of refrigerant gas is fed to the suction inlet of the first compressor body and a second stream of refrigerant gas is fed to the suction inlet of the second compressor body, a second compression stage for compressing the mixed refrigerant gas, and a first merging means for recombining the first stream of refrigerant gas with the second stream of refrigerant gas downstream of the first compression stage for delivery to the second compression stage.
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1. A refrigerant circuit for use in a liquefaction plant, the refrigerant circuit comprising: a first compression stage for compressing an evaporated mixed refrigerant gas from a first pressure to a second pressure, wherein the mass flow of the mixed refrigerant gas being compressed in the first com
1. A refrigerant circuit for use in a liquefaction plant, the refrigerant circuit comprising: a first compression stage for compressing an evaporated mixed refrigerant gas from a first pressure to a second pressure, wherein the mass flow of the mixed refrigerant gas being compressed in the first compression stage is constant through the first compression stage, and the first compression stage comprises at least a first compressor body including a first compressor body casing for the evaporated mixed refrigerant gas passing the first compressor body casing, and a second parallel compressor body including a second compressor body casing for the evaporated mixed refrigerant gas passing the second compressor body casing, the first compressor body casing is separate from the second compressor body casing, and each of the first and second compressor bodies includes a suction inlet and an outlet;a first distribution means for splitting the mass flow of refrigerant gas to the first stage of compression evenly across the suction inlet of the first compressor body and the suction inlet of the second compressor body, such that a first stream of refrigerant gas is fed to the suction inlet of the first compressor body and a second stream of refrigerant gas is fed to the suction inlet of the second compressor body;a second compression stage for compressing the mixed refrigerant gas from the second pressure to a third pressure, wherein the mass flow of the mixed refrigerant gas being compressed in the second compression stage is constant through the second compression stage, the second compression stage comprising a single compressor body including a single compressor body casing for the evaporated mixed refrigerant gas passing through the single compressor body, and a pre-cooling compressor for compressing a refrigerant different to the evaporated mixed refrigerant, and wherein the single compressor body casing of the second compression stage is separate from the first compressor body casing of the first compression stage and the single compressor body casing of the second compression stage is separate from the second compressor body casing of the first compression stage; anda first merging means for recombining the first stream of refrigerant gas with the second stream of refrigerant gas to form a combined stream downstream of the first compression stage for delivery to the single compressor body of the second compression stage;wherein: the compressor bodies of the first stage are mounted on a first common shaft driven by a first drive; andthe pre-cooling compressor and at least one of the compressor bodies of the second stage are mounted on a second common shaft driven by a second drive. 2. The refrigerant circuit of claim 1, further comprising a first intercooling heat exchanger for removing heat of compression from the refrigerant, wherein the first intercooling heat exchanger is arranged between the first compression stage and the second compression stage. 3. The refrigerant circuit of claim 2, wherein the first merging means is arranged upstream of the first intercooling heat exchanger. 4. The refrigerant circuit of claim 1, wherein the mass flow rate of the first stream of refrigerant fed to the suction inlet of the first compressor body is equal to the mass flow rate of the second stream of refrigerant fed to the suction inlet of the second compressor body. 5. The refrigerant circuit of claim 1, wherein each of the at least two parallel compressor bodies is capable of compressing a suction volumetric flow rate of refrigerant gas of at least 100,000 m3/h or at least 150,000 m3/h or at least 200,000 m3/h. 6. The refrigerant circuit of claim 1, further comprising a third compression stage for compressing the mixed refrigerant gas from the third pressure to a fourth pressure, wherein the mass flow of the mixed refrigerant gas being compressed in the third compression stage is constant through the third compression stage. 7. The refrigerant circuit of claim 6, further comprising a second intercooling heat exchanger arranged between the second compression stage and the third compression stage for removing heat of compression from the refrigerant. 8. The refrigerant circuit of claim 6, wherein the second and third compression stages are combined within a single back to back compressor body. 9. A plant for the production of a liquefied hydrocarbon product such as liquefied natural gas, the plant comprising: a main heat exchanger in which natural gas is liquefied by indirect heat exchange with an evaporating mixed refrigerant; andthe refrigerant circuit of claim 1 for compressing the evaporated refrigerant for re-use in the main heat exchanger system. 10. The plant for the production of a liquefied hydrocarbon product of claim 9, wherein the first distribution means is arranged upstream of the main heat exchanger system. 11. A method for cooling or liquefying a hydrocarbon stream, wherein the hydrocarbon stream to be cooled by indirect heat exchange with an evaporating refrigerant, and the evaporated refrigerant is cooled using a refrigerant circuit, the method comprising: compressing an evaporated mixed refrigerant gas from a first pressure to a second pressure in a first compression stage, wherein the mass flow of the mixed refrigerant gas being compressed in the first compression stage is constant through the first compression stage, and the first compression stage comprises at least a first compressor body including a first compressor body casing for the evaporated mixed refrigerant gas passing the first compressor body casing, and a second parallel compressor body including a second compressor body casing for the evaporated mixed refrigerant gas passing the second compressor body casing, the first compressor body casing is separate from the second compressor body casing, and each of the first and second compressor bodies includes a suction inlet and an outlet;splitting the mass flow of refrigerant gas to the first stage of compression evenly across the first and second compressor bodies, such that a first stream of refrigerant gas is fed to the suction inlet of the first compressor body and a second stream of refrigerant gas is fed to the suction inlet of the second compressor body;compressing the mixed refrigerant gas from the second pressure to a third pressure in a second compression stage, wherein the mass flow of the mixed refrigerant gas being compressed in the second compression stage is constant through the second compression stage, the second compression stage comprising a single compressor body including a single compressor body casing for the evaporated mixed refrigerant gas passing through the single compressor body, and wherein the single compressor body casing of the second compression stage is separate from the first compressor body casing of the first compression stage and the single compressor body casing of the second compression stage is separate from the second compressor body casing of the first compression stage;recombining the first stream of refrigerant gas with the second stream of refrigerant gas to form a combined stream downstream of the first compression stage for delivery to the single compressor body of the second compression stage;driving the compressor bodies of the first stage on a first common shaft driven by the same drive:using a pre-cooling compressor to compress a refrigerant which is different to the evaporated mixed refrigerant; anddriving the pre-cooling compressor and at least one of the compressor bodies of the second stage are mounted on a second common shaft driven by a second drive. 12. The method of claim 11, further comprising: removing heat of compression from the refrigerant in a first intercooling heat exchanger, wherein the first intercooling heat exchanger is arranged between the first compression stage and the second compression stage. 13. The method of claim 12, wherein the first merging means is arranged upstream of the first intercooling heat exchanger. 14. The method of claim 11, wherein the mass flow rate of the first stream of refrigerant fed to the suction inlet of the first compressor body is equal to the mass flow rate of the second stream of refrigerant fed to the suction inlet of the second compressor body. 15. The method of claim 11, wherein each of the at least two parallel compressor bodies is arranged to receive a suction volumetric flow rate of refrigerant gas of at least 100,000 m3/h or at least 150,000 m3/h or at least 200,000 m3/h. 16. The method of claim 11 further comprising: compressing the mixed refrigerant gas from the third pressure to a fourth pressure in a third compression stage, wherein the mass flow of the mixed refrigerant gas being compressed in the third compression stage is constant through the third compression stage. 17. The method of claim 16, further comprising: removing heat of compression from the refrigerant in a second intercooling heat exchanger arranged between the second compression stage and the third compression stage. 18. The method of claim 16, wherein the second and third compression stages are combined within a single back to back compressor body.
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이 특허에 인용된 특허 (21)
Wilding,Bruce M.; Bingham,Dennis N.; McKellar,Michael G.; Turner,Terry D.; Raterman,Kevin T.; Palmer,Gary L.; Klingler,Kerry M.; Vranicar,John J., Apparatus for the liquefaction of natural gas and methods relating to same.
Kikkawa Yoshitsugi (Kanagawa-ken JPX) Yamamoto Osamu (Kanagawa-ken JPX) Naito Yasuhiro (Kanagawa-ken JPX) Sakaguchi Junichi (Kanagawa-ken JPX), Compressor drive system for a natural gas liquefaction plant having an electric motor generator to feed excess power to.
Low William R. (1000 Grandview Rd. Bartlesville OK 74006) Andress Donald L. (306 Stoneridge Bartlesville OK 74006) Houser Clarence G. (1803 SE. Harned Dr. Bartlesville OK 74006), Method of load distribution in a cascaded refrigeration process.
Rudolf Stockmann DE; Manfred Bolt DE; Manfred Steinbauer DE; Christian Pfeiffer DE; Pentti Paurola NO; Wolfgang Forg DE; Arne Olav Fredheim NO; Oystein Sorensen NO, Process for liquefying a hydrocarbon-rich stream.
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