TH106792A - Methods and systems of liquid state formation - Google Patents

Abstract

DC60 (04/02/53) Method for creating liquid state using closed loop cooling system, whereby the method It consists of the process of (a) the compression of the refrigerant in the gaseous state in one or more compressors (b) the refrigerant flow in the compressed gas state in the exchanger. The first heat (c) causes at least part of the refrigerant's current in a gaseous state. The compress, which has cooled down from the heat exchanger on one of the expander one, is expanded. To obtain the refrigerant flow in the first gaseous expansion and (d) cooling the feed gas flow and having a liquidity characteristic. To obtain a feed gas flow, which is characterized by the presence of a liquid state in the machine. Second heat exchanger by means of indirect heat exchange as opposed to at least region. Part of the refrigerant flow in the gas state with one expansion from the heater Expanding at one where the refrigerant stream in the gas state is expanding at one that exits the machine. Causing the expansion that one would be characterized by as a vapor Liquid state formation using a closed loop cooling system where It consists of the process of (a) the compression of the refrigerant in the gaseous state in one or more compressors (b) the refrigerant flow in the compressed gas state in the exchanger. The first heat (c) causes at least part of the refrigerant's current in a gaseous state. The compress, which has cooled down from the heat exchanger on one of the expander one, is expanded. To obtain the refrigerant flow in the first gaseous expansion and (d) cooling the feed gas flow and having a liquidity characteristic. To obtain a feed gas flow, which is characterized by the presence of a liquid state in the machine. Second heat exchanger by means of indirect heat exchange as opposed to at least region. Part of the refrigerant flow in the gas state with one expansion from the heater Expanding at one where the refrigerant stream in the gas state is expanding at one that exits the machine. Causing the expansion that one would be characterized by as a vapor

Claims (1)

Disclaimer (all) which will not appear on the advertisement page: EDIT 18/03/2016 1. How to generate liquid state using closed loop cooling system utilized. From the isentropic expansion of the refrigerant in a gaseous state by which the method It consists of the process of (a) the compression of the refrigerant in the gaseous state in one or more compressors (b) the refrigerant flow in the compressed gas state in the exchanger. The first heat is below the ambient temperature, creating a cooled compressed refrigerant stream (c), making at least part of the refrigerant's stream in a compressed gas state, which Then cooled in the first expander, expanding to obtain the refrigerant flow in the Gas that is expanding at one, where the refrigerant flows in the gas at one expansion which exits from The first expander is characterized primarily as a vapor (d) cooling of the feed gas stream and is characterized as being a Liquids to obtain the feed gas flow, which is characterized by the formation of a liquid state in Second heat exchanger, based on indirect heat exchange, as opposed to at least Part one of the refrigerant stream in the first expansion gaseous state from the first expander (e) separation of the second part of the refrigerant flow in the gaseous expansion at One out of part of the refrigerant flow in a gaseous state with that one expansion From the position in the middle of the second heat exchanger to balance the range of Pre-cooling of the second heat exchanger and (f) separation of the refrigerant in the first expansion gaseous state. From the part of the refrigerant flow in the gaseous state with the first expansion thereof The heated end of the aforementioned second heat exchanger 2. Method according to claim 1, whereby the refrigerant flow in the aforementioned gas state is Nitrogen flow 3. Method according to claim 1, which also includes the storage of gas flows for The feeder is cooled and is characterized as a liquid in a high-pressure storage tank. 4. Method of claim 1, which is described above, also consists of arrangements for processing. Cooling as a complement to the first heat exchanger by means of a heat exchange Indirectly with an auxiliary cooling system consisting of the refrigerant which is the power liquid To vapor at least one period 5. Method of claim 4, where the refrigerant is a liquid that is vaporizing. It contains CO2, methane, propane, butane, iso-butane, propylene, ethane, ethylene, R22, HFC-based refrigerants including R410A, R134A, R507, R23 or a combination of them 6. Method according to claim 1, whereby the feed gas stream to form a liquid state is Natural gas flow 7. Method according to claim 6, where liquid state is created on board natural gas. For production, storage and emission (FPSO) used. 8. Method of claim 1, where part of the refrigerant flow in the gaseous state. The first expansion from the first expander makes the feed gas flow through the exchanger. Indirect heat is cooled in the second heat exchanger in step (d) of claim 1, and by the second part of the refrigerant stream in the first gaseous state from the expander. First, it causes the second part of the refrigerant stream in the cooled gas state of the machine. The first heat exchanger is cooled in the third heat exchanger 9. Method according to claim 8, where the third part of the refrigerant flow in the gaseous state. One expander, which exits the expander, where one is heated in the heat exchanger at Third, before the expansion into the second expansion device 10. Method for claim 8 whereby the first heat exchanger and exchanger The third heat exchanger is an anodized aluminum (core) heat exchanger with articulated plates and fins. 11. The method of claim 1, which, as mentioned above, also consists of extremely cool rendering. with The cooled feed gas stream is characterized as a liquid by means of an exchange. Indirect heat in an exchanger with a supercooler, as opposed to the refrigerant stream in The second expansion gas state exiting the secondary expander where the refrigerant stream in The second expanded gas state that exits the second expander is characterized primarily as vapor 12. The method of claim 11, which, as mentioned above, also consists of compressing the gas stream. For feeders where the cooled liquid state is formed, the separation of the feed gas with the Creates a refrigerated liquid state in the cyclonic separator to produce liquid and vapor products. Evaporation, where such sudden vapors can be compressed, heated and used as fuel. 13. Method for claim 11 where the second heat exchanger and exchanger With such an even cooler, it is a coiled heat exchanger 14. Method according to claim 11, where the compression of the refrigerant in the gaseous state in accordance with the procedure (a) of the claim at 1 is due to (a) (1) air compression of the refrigerant in the gaseous state in the low pressure compressor and (a) (2) the compression of the refrigerant in the additional gaseous state in the high pressure compressor.15. The method for claim 14, which, as mentioned above, also consists of making the second part of The refrigerant stream in the first gaseous state expands from the first expansion heater. In the third heat exchanger and the first heat exchanger, in order to obtain the reagent flow, Cooling in the warmer gas state and conduction of refrigerant in the warm gas state is mixed. To the refrigerant flow in the compressed gas state that exits the low pressure compressor during phases (a) (1) and (a) (2) of claim 14 16. Claim Method 14th, which, as mentioned above, also consists of heating the machine Exchange the first heat to the second part of the refrigerant stream in the sorted gaseous state. Out of the position between the middle of the second heat exchanger and the conduction of the substance Cooling in the heated gas state is mixed with the refrigerant stream in the compressed gas state. From the low-pressure compressor during the (a) (1) and (a) (2) phases of claim 14 17. The method of claim 14, which, as mentioned above, also consists of separating the flow of the substance. Cooling in the compressed gas state that is released from the high pressure compressor, making the part of the The refrigerant flow in a compressed gas state that leaves at least one compressor is Expands in the third expander, making the part of the expanding refrigerant stream. In the compressed gas state in the first heat exchanger, it is warmed up and then the first part is taken. Which is heated expansion of the refrigerant stream In a gas that has been mixed with Refrigerant flow in the compressed gas state that leaves the compressor at low pressure during phases (a) (1) and (a) (2) of claim 14 and making the second part of the substance flow. Cooling in The compressed gas state that is released from the high pressure compressor is cooled in the heat exchanger at one of the steps (b) of claim 1 18. Method according to claim 14 whereby the pressure of the current of Refrigerant in a gas state at The second expansion which exits the second expander is lower than d of the rheostat current. 19. The method of claim 18, which, as mentioned above, also consists of the separation of the flow of the substance. Cooling in the compressed gas state that is released from the high pressure compressor, making the part of the The refrigerant flow in the compressed gas state exiting the high pressure compressor expands in the Third expansion, making the part of the expanded refrigerant stream in a state The compressed gas in the first heat exchanger has a warmer state, and then the part where the The warmed expansion of the refrigerant stream in a compressed gaseous state is mixed with the current. Of the refrigerant in the compressed gas state that leaves the compressor at low pressure during the (a) (1) and (a) (2) phases of claim 14 and the making of the second part of the refrigerant stream Cool in gaseous state The compressed air that is discharged from the high-pressure compressor is cooled into the heat exchanger at step one (b) of claim 1 20. The method according to claim 14, which also includes: Separate streams of substances Cooling in the compressed gas state that is released from the high pressure compressor, making the part of the The refrigerant stream in the compressed gas state that leaves the high pressure compressor cools. In an optional cooling system that contains the refrigerant, the liquid is becoming At least one period of vapor and conduction of the cooled part of the refrigerant stream in The compressed gas state is mixed with part of the refrigerant flow in the compressed gas state. Cooled from the first heat exchanger to allow expansion in the expander at one of the (c) steps of claim 1 and where the second part of the refrigerant flow in the gaseous state. That's right The compress, which is exited from the high-pressure compressor, is cooled in the heat exchanger at one of the steps (b) of claim 1 2 1. The method of claim 20, which also includes Gasification For feeding there is a pre-cooling condition in the optional cooling system that contains the refrigerant. At least one period prior to the procedure (d) of claim 1 22. Method of claim 21 where the complementary cooling system is used for the cooling of the liquid to be vaporized at least one period before the procedure (d) of claim 1. The feed gas is pre-cooled and an optional cooling system for the One of the refrigerant flows in a compressed gas state that leaves the high-pressure compressor cools down. It is a single complementary cooling system. 2. 3. Closed-loop system for liquid state formation utilizing vapor expansion. It consists of: - Refrigerant compressor - One heat exchanger connected to the refrigerant compressor at It is low pressure in such a way that fluids can flow smoothly and are optimized to at least Part of the refrigerant flow in a gaseous state is compressed into by the compressor of the refrigerant. Such cooling - First expander attached to the first heat exchanger in Characteristics in which fluids can flow consecutively and have been tuned to accept at least part of the A stream of cooled compressed refrigerant enters from the first heat exchanger - the second expander attached to the first heat exchanger. Characteristics in which fluids can flow consecutively and have been tuned to accept at least part of the An expanded refrigerant stream enters from the one such heat exchanger where At least one such part of the expanded refrigerant flow is characterized primarily as a vapor-first pipeline for separating one portion of the refrigerant's flow in a gas-filled state. The expansion from the second heat exchanger leaves the midway position of the machine. Heat exchanger to balance the pre-cooling range of the exchanger. Second Heat - A second pipeline for separating at least the second part of the refrigerant stream in The expanded gas state from the second heat exchanger leaves the heated end of the unit. Such a second heat exchanger, and - a third pipeline for the discharge of gas streams for feeding in the second heat exchanger. To generate a feed gas stream, which is characterized by its liquid state generation through Indirect heat exchanger, as opposed to at least part of the refrigerant current in The gas state that is expanded from the first expansion unit. 24. Method of claim 23 where the refrigerant flow in the gaseous state is Nitrogen stream 2 5. System according to claim 23 where the first heat exchanger and the exchanger The third heat exchanger is an anodized aluminum (core) heat exchanger with splice plates and 2 fins. 6. System according to claim 23, which, as mentioned above, also consists of - the compressor of the refrigerant. One low voltage connected to the exchanger And - a second low-pressure refrigerant compressor connected to an exchanger. The third heat in such a way that the fluid can flow consecutively and 27. system according to claim 23, where the gas stream for entering the liquid state is Natural gas flows 28. System in accordance with claim 27, where such systems are used on board ships for the production, storage and offloading (FPSO). Then also includes a exchange machine The third hot and the heat exchanger by the coolant, where the exchanger with the cooler It is attached to a third heat exchanger and a second expander in a manner. Where fluids can flow consecutively and are tuned to accept gas flow from The aforementioned third heat exchanger 30. System according to claim 29, where the third heat exchanger and exchanger With such a coolant, it is a coil heat exchanger that is wound up. 31. The system according to claim 29, which, as mentioned above, also consists of The tongue that is attached to the heat exchanger with the coolant even more so that the flow of It can flow continuously, which is optimized to receive a gas flow for the machine. Exchanging heat with an even cooler and The phase separator is attached to the valve in such a way that the fluid can flow. They are continuous and are optimized to separate the feed gas stream into the fluid products. 32. The system according to claim 23, which, as mentioned above, also consists of (a) low pressure refrigerant compressor connected to an exchanger. Heat first in such a way that the fluid can flow continuously, and (b) the compressor of the refrigerant with low pressure, which is connected in such a way that the fluid Can flow together with the first heat exchanger and the compressor of the refrigerant. A low pressure cooler that has been optimized to receive refrigerant flow in from the exchanger. First heat and low pressure refrigerant compressor 33. The system according to claim 32, which is mentioned above, also consists of a cooling system that is The add-ons are attached to the compressor of the high-pressure refrigerant in a fluid manner. It can flow continuously and is fine-tuned to accept the refrigerant flow in a gaseous state. 3 4. System according to claim 32, which, as mentioned above, also consists of a third expander. That is connected to the compressor of refrigerant at high pressure in such a way that the fluid can flow Contactable and tuned to accept part of the refrigerant's flow in a gaseous state at 35. The system according to claim 32, which is mentioned above, also consists of a refrigeration system that is high-pressure. The add-on is optimized to provide cooling for the first heat exchanger where the system The optional cooling contains the refrigerant, a liquid that is vaporizing. At least one period 36. System according to claim 35, where the refrigerant, a liquid that is vaporizing It contains CO2, methane, propane, butane, iso-butane, propylene, ethane, ethylene, R22, HFC-based refrigerants including R410A, R134A, R507, R23 or a combination of them 37. Method of generating liquid state using closed loop cooling system. It consists of the process of (a) compression of the refrigerant in the gaseous state in at least one compressor, (b) making at least part of the refrigerant's compressed gas stream. Cooling in the first heat exchanger (c), cooling part of the refrigerant stream in a cooled compressed gas state Then, from the first expander, expansion occurs in the first heat exchanger to obtain Refrigerant flow in the first gaseous expansion (d) cooling of the feed gas flow is characterized by Liquids to obtain the feed gas flow, which is characterized by the formation of a liquid state in Second heat exchanger with indirect heat exchanger as opposed to one Of the refrigerant stream in the gaseous state with first expansion from the first expansion and (e) the second cooling of the refrigerant stream in the compressed gas state Then from one heat exchanger is cooled to another in the third heat exchanger by Exchanging heat indirectly with the second part of the refrigerant stream in a gaseous state with Expansion one from the first expansion device 38. The method of claim 37, which is also mentioned above, also consists of gasification. For a cooler feeder and characterized by a more fluid cooling condition by means of an exchange Indirect heat in the heat exchanger with an extremely coolant, as opposed to the conductive stream. Cooling in the second expansion gas state exiting the second expander 3. 9. Method according to claim 38, where the second part of the cooled feed gas stream has The main characteristic is such a liquid after it is further cooled in the heat exchanger. The third is fed to the second expander to obtain the refrigerant flow in the gaseous state. The second expansion 4 0. Method according to claim 39, where the refrigerant flow in the gas expansion state The second exiting the second expander is characterized by a significant vapor stream. 4. 1. Method according to claim 39, where the refrigerant flow in the gaseous state is expanded. The second, exiting the exchanger with the coolant, is compressed in a low-pressure compressor, mixed with a part of the refrigerant flow in the first expanding gas state exiting the machine. The second heat exchanger and the second part of the refrigerant flow in a gaseous state with The first expands from the third heat exchanger and the mixed currents are compressed. High-pressure compressor 4 2. Method of claim 37, which also consists of making at least part That one part of the refrigerant's flow in a gaseous state is expanding at one that exits The second heat exchanger is heated in the first heat exchanger. 4. 3. The method of claim 37, which, as mentioned above, also consists of making the second part of the heat exchanger. The refrigerant stream in the gas state has one expansion that leaves the heat exchanger at Third, the heated condition in the first heat exchanger. 4 4. The method of claim 37, which, as mentioned above, also consists of separating the current of the substance. Cooling in a compressed gas state that is exited from one or more compressors into the first and second parts, such first cooling in an optional cooling system consisting of Refrigerant which is a liquid that is going to vaporize at least one phase, the second such a Cooled in the heat exchanger at step one (b) of claim 37 and taking part one. Which was cooled to mix with the second part which was cooled to allow expansion in the humidifier. Expand one of the steps (c) of claim 37 4. 5. The method of claim 37, which is described above, also consists of separating the flow of substances. Refrigerating in a compressed gas state that leaves at least one compressor into the first and second, the first expansion in the third expansion, the partial that One, which is expanded with a heated condition in the first heat exchanger and the second heating. It is cooled in the heat exchanger at one of the steps (b) of claim 37 4 6. Method of claim 37 whereby the feed gas stream to form a liquid state is Natural gas flow 47. Method for claim 37 whereby the refrigerant flow in the gas state is Nitrogen stream 4 8. Closed-loop system for generating a liquid state consisting of A cooling cycle where the aforementioned cooling cycle consists of First compressor - one heat exchanger connected to the first compressor in such a way that The fluid can flow continuously and has been adjusted to accept the refrigerant flow in the The gas state comes in from the aforementioned compressor. - one expander attached to the first heat exchanger as mentioned in The manner in which fluids can flow continuously and are optimized to receive the cleaning fluid stream. Cold in a gas with one expansion coming from the first expander and feed gas stream - third heat exchanger connected to the first heat exchanger. And to the first expansion in such a way that the fluids can flow continuously and get Adjusted to get a second current of refrigerant incoming from the first heat exchanger and Refrigerant stream in a gaseous state with a second expansion from the first expander. - a second expander which is attached to the third heat exchanger in a manner Where the fluid can flow continuously and has been adjusted to accept the refrigerant flow From the aforementioned third heat exchanger - exchanger with a coolant coupled to a second heat exchanger And a second expander in such a way that the fluids can flow consecutively and are adjusted In order to receive the input gas stream from the second heat exchanger and the conductive current The cooling in the gas state is enlarged from the second expansion unit. Where the first heat exchanger and the third heat exchanger may be Integrated into a single heat exchanger and Where the second heat exchanger and the aforementioned coolant exchanger 4. 9. Method of forming liquid state using closed loop cooling system (a) compression of refrigerant in gaseous state in one or more compressors. (b) Making at least part of the refrigerant's stream in a compressed gas state. Cooling in the first heat exchanger (c), eliminating the refrigerant stream in the cooled compressed gas state from the Between the middle of the first heat exchanger and the making of that part of the stream of the substance The cooling in the cooled compressed gas state is expanded from the One of the first amplifiers to obtain the refrigerant flow in the first gaseous (d) expansion of the feed gas flow is characterized as Liquids to obtain the feed gas flow, which is characterized by the formation of a liquid state in Second heat exchanger with indirect heat exchanger as opposed to one Of the refrigerant stream in the gaseous state with first expansion from the first expansion and (e) the second cooling of the refrigerant stream in the compressed gas state Then in one heat exchanger is cooled further in the third heat exchanger by Exchanging heat indirectly with the second part of the refrigerant stream in a gaseous state with Inflate one from one inflator Where the refrigerant flow in a gas state with one expansion that leaves the heater The first expansion is characterized by a vapor 50. The method of claim 49, which is mentioned above, also consists of gas flow. For a cooler feeder and characterized by a more fluid cooling condition by means of an exchange Indirect heat in a second heat exchanger with an even cooler, as opposed to the current of Refrigerant in the second expansion gas state exiting the second expander 51. Method according to claim 50, where the second part of the cooled feed gas stream has The main characteristic is such a liquid after it is further cooled in the heat exchanger. One is fed to the second expander to obtain the refrigerant flow in the gaseous state. There is a second expansion 52. Method according to claim 51 where the refrigerant flow in the gas state is expanded. The second exits the second expander is characterized primarily by the vapor flow 53. The method of claim 49, which, as mentioned above, also consists of gasification. For a cooler feeder and characterized by a more fluid cooling condition by means of an exchange Indirect heat in an exchanger with a supercooler, as opposed to the refrigerant stream in The second expansion gas state exiting the second expander 5 4. Method according to claim 49 where the feed gas stream to form the liquid state is Natural gas flow 55. Method for claim 49 whereby the refrigerant flow in the gas state is Nitrogen stream 5 6. Closed-loop system for generating a liquid state consisting of A cooling cycle where the aforementioned cooling cycle consists of First compressor - one heat exchanger connected to the first compressor in such a way that The fluid can flow continuously and has been adjusted to accept the refrigerant flow in the The gas state comes in from the aforementioned compressor. - one expander attached to the first heat exchanger as mentioned in Characteristics in which fluids can flow consecutively and are tuned to accept part of the flow of Refrigerant, in a cooled compressed gas state, enters from an intermediate position of the unit. One heat exchanger - a second heat exchanger which is attached to the first expander and receives Adjustment to receive the refrigerant flow in an expanded gas state that one enters the unit. The first expansion and the gas flow - a second expander which is attached to the first heat exchanger in a manner Where fluids can flow consecutively and are tuned to accept the second part of the fluid flow Cold in the cooled compressed gas state comes from the first heat exchanger. Where one of the aforementioned heat exchanger has been adjusted to receive the current A second expansion gaseous refrigerant enters from the first expander and where The aforementioned second heat exchanger is optimized to carry the refrigerant stream in The expanded gas state comes in from the second inflator. -------------------------------------------------- ---------------------------------------- 1. Method for generating liquid state using closed loop cooling system where the method It consists of the procedure of (a) compression of the refrigerant in gaseous state in at least one compressor (b) cooling the refrigerant flow in the compressed gas state in the exchanger. First heat (c) causes at least part of the refrigerant's current in a gaseous state. Is compressed, which is cooled by the heat exchanger on one of the first expansion expander. To obtain the refrigerant flow in the first gaseous state, and (d) cooling the feed gas flow and is characterized as Liquids to obtain the feed gas flow, which is characterized by the formation of a liquid state in Second heat exchanger by means of indirect heat exchange as opposed to area At least part of the refrigerant flow in the gaseous state has one expansion from the heater. To expand at one Where the refrigerant flow in a gas state with the first expansion that leaves the heater Given the expansion that one would be characterized by as a vapor.