TH27033B - Cooling the stream of fluid - Google Patents

Abstract

The cooling method for the fluid stream passing through the hot side (1d, 1b, 1c) of the main heat exchanger (1) consists of taking the refrigerant from Primary heat exchanger (1); Refrigerant compression in a two-stage (7) compression unit to obtain high-pressure refrigerant; Partially tightening the refrigerant at high pressure (12) to obtain a two-state fluid, the first fluid, and the separation (13) of the first two-state fluid into a liquid separator. Part one (15) and part one (16) gaseous part; Cooling of the first liquid separator (15) in the auxiliary heat exchanger (2) to obtain the cool part one liquid separator (18), cooling for the part The separator is the first part (16) gas in the exchanger. Supplementary heat (2) to obtain a dual-state fluid. The second fluid (26) by cooling is achieved by a liquid that is vaporized at a medium pressure on the cold side (2a); The second fluid-state separation (28) into the second liquid-liquid separation (33) and the second gas-liquid separation (32); Permission of a second part of the liquid separator (49) to vaporize in the cold side (2a) of the auxiliary heat exchanger (2); And cooling for the remainder of the second liquid separator (33) in the main heat exchanger (1) to obtain the second liquid separator cooling, and cooling. Down for the second gaseous separation in the main heat exchanger (1), by cooling. This is achieved by liquid vaporizing at low pressure on the cold side (1a) of the main heat exchanger (1).

Claims (4)

1. Methods of cooling for fluid flows Which flows through the hot side of Primary heat exchanger The methodology includes the steps of: (a) removing the refrigerant from the cold side of the primary heat exchanger; (b) Compression of the refrigerant in a multi-stage compressor unit from low pressure through a value pressure. At least one medium value is the high pressure. To obtain high pressure refrigerant; (c) Partial condensation of the refrigerant obtained in step (b) to obtain fluid. The first two-state fluid, and the first two-fluid separation. Is the first liquid separator And the part that is the first gas; (d) Cooling of the first liquid separator on the hot side of the machine. Auxiliary heat exchanger To obtain a cold part of the liquid separation; (e) allowing the cold, first liquid separator to vaporize at a nominal pressure in The cold side of the auxiliary heat exchanger To obtain the refrigerant at medium pressure which is then delivered to the medium term inlet of the unit. Multi-stage compressors; (f) partial condensation of the gaseous fraction on the hot side of the second side of Auxiliary heat exchanger To obtain a second fluid state, second fluid state; (g) the second fluid-state separation into the final secondary and the final secondary gas-liquid separation; (h) Cooling for the last secondary liquid separator on the hot side one of the Primary heat exchanger To obtain the cool final secondary liquid separation; (i) allowing the cold last secondary liquid separator to vaporize at low pressure in The cold side of the main heat exchanger To obtain refrigerant at low pressure Which thereafter will be delivered to the inlet of phase one of the multi stage compression unit; (j) Cooling for the last secondary gas-liquid separator on the hot side of the second Primary heat exchanger To obtain the cool final liquid separation; And (k) allowing the cold last liquid separator to vaporize at low pressure on the cold side. Of primary heat exchanger To obtain the refrigerant at low pressure which is then delivered to the inlet of the first stage of the multi-stage compressor unit, it is characterized by that part of the split As the last secondary liquid obtained in the (g) process, it is allowed to vaporize at the medium pressure on the cold side of the exchanger. 2. The method as in Clause 1, where the volume of the separate parts is The last secondary liquid obtained in the (g) step, is allowed to vaporize at the nominal pressure. On the cold side of the auxiliary heat exchanger, it is between 5 and 50% by the mass of the The final secondary liquid 3. The methodology as it holds in claim 1, where the procedure (g) includes The second fluid separation is the second liquid separation and the second gas phase separation; Cooling for the second liquid separator on the side Heat the first side of the second auxiliary heat exchanger. In order to obtain a separate part that is The second liquid that cools; To allow the cold second liquid separator to vaporize Second lower median pressure on the cold side of the second auxiliary heat exchanger to obtain the refrigerant at the secondary medium pressure. Which will then be delivered to the channel Into the lower median pressure range of the multi-stage compression unit; Making a separate part that is The second part of the gas is partially condensed on the second hot side of the auxiliary heat exchanger. Second machine In order to obtain a dual-state fluid of a third fluid; And separation of fluids Two states of fluid, the third into the liquid separator, the last secondary. And the gas separator The last part Where part of the second liquid separator is allowed to vaporize. At the median pressure on the cold side of the auxiliary heat exchanger And where part of the split The last secondary fluid is allowed to vaporize at a medium pressure on the cold side of the Source heat exchanger 4. Methodology as held in Clause 3, where the volume of the split Second part liquid Which is allowed to vaporize at a medium pressure on the cold side of the machine The auxiliary heat exchanger is between 5 and 50% by the mass of the second part of the liquid separator. 5. Methodology as held in Clause 3 or 4, where the volume of the split part is Final secondary liquid Which is allowed to vaporize at a medium pressure on the cold side of the machine The source auxiliary heat exchanger is between 5 and 50% by the mass of the liquid separator Part II 6. Methodology as held in any of Clause 3 to 4. Where part of The last secondary liquid separator. Is allowed to vaporize at the second central pressure 7. The methodology as set forth in any of Clause 3 to 4 of Claims 3 to 4 is lower on the cold side of the second auxiliary heat exchanger. Where part of The last secondary liquid separator is allowed to vaporize at the mean pressure in Cold side of the additional heat exchanger 8. Methodology as in any of Clause 1 to 7. Where the flow of The fluid is pre-cooled on the hot side of the auxiliary heat exchanger and thereafter is passed to the hot side of the main heat exchanger. 9. The unit for cooling the fluid stream is assembled. Included with the main heat exchanger it is equipped with cold side and hot side. Where the flow of the received fluid The cooling can be obtained through a flow, an additional heat exchanger that has been Provide at least two cold side and hot side, multistage compression unit, the outlet of the cold side of the main heat exchanger is connected to the inlet of phase one. And the outlet of the cold side of the auxiliary heat exchanger is connected to the Inlet of the medium pressure stage, the main gas-liquid separator where the inlet is connected to the The condenser is connected to the final outlet of the multi-stage compression unit where the fluid outlet is connected to the inlet of the hot side. At one of the auxiliary heat exchanger And which the vapor outlet has been connected to Inlet of the second hot side of the auxiliary heat exchanger Gas-liquid separator The last machine where the inlet will be connected to the hot side outlet of the second side of the An auxiliary heat exchanger, in which the fluid outlet port is connected to the Entrance of the first hot side of the main heat exchanger And which outlet for vapor It will be connected to the inlet of the second hot side of the main heat exchanger. Where the outlet of the hot side one of the auxiliary heat exchanger is connected to With the cold side of the auxiliary heat exchanger By means of the manifold provided, there is a pressure relief device and where the outlet of the first hot side and the second hot side of the exchanger. The primary heat is connected to the cold side of the main heat exchanger by means of a manifold provided with a pressure reducing device. Is unique because the outlet of the machine The final gas-liquid separator was also connected to the cold side of the auxiliary heat exchanger by means of a manifold provided with a 1 0 pressure reducing device. In Clause 9, where the heat exchanger is supplemented At least it will include First and second auxiliary heat exchangers Each machine is provided with two cold and hot sides, where the outlet of the The cold side of the first auxiliary heat exchanger is connected to the inlet of the last stage, the cold side of the second auxiliary heat exchanger is It is connected to the inlet, the lower mean pressure distance, etc., where the outlet for the liquid Of the main gas-liquid separator is connected to the inlet of the hot side one of the First auxiliary heat exchanger And the gas outlet port has been connected to Second hot side inlet, where the hot side exchanger The first auxiliary heat is connected to the cold side by means of a channel provided. The pressure reducing device, where the second hot side outlet port is connected to the inlet Of the first gas-liquid separator, where the liquid outlet of the first gas-liquid separator is connected to the inlet of the first hot side of the gas-liquid separator. Second heat exchanger And the gas outlet port has been connected to the Entrance of the second hot side, where the outlet of the hot side one of the exchanger The second auxiliary heat will be connected to the cold side. By relying on the pipeline that has been provided to have The pressure reducing device, where the second hot side outlet port is connected to the inlet Of the second gas-liquid separator, etc., and where the outlets of the first and second gas-liquid separators Has been connected to the cold side of the exchanger. First and second additional heat as well. By means of the inlet pipe provided with a pressure reducing device 1 1. The machine is completed according to claim No. 9 or 10, where the Multiple stages are combined with two stage presses arranged in parallel 1. 2. The machine is completed according to claim No. 11, where the number of Several phases in parallel are two to four. 3. The machine is successful as it holds in any of Clause 9 to 12. Where the machine Any one of the primary and auxiliary heat exchangers, consisting of two units, or More than that in parallel 1 4. The machine is successful as it holds in any of Clause 9 to 13. Where the machine The auxiliary heat exchanger consists of a hot side for pre-cooling of the fluid stream, which an outlet channel is connected to the hot side of the primary heat exchanger.