US3854301A - Cryogenic absorption cycles - Google Patents
Cryogenic absorption cycles Download PDFInfo
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- US3854301A US3854301A US00152332A US15233271A US3854301A US 3854301 A US3854301 A US 3854301A US 00152332 A US00152332 A US 00152332A US 15233271 A US15233271 A US 15233271A US 3854301 A US3854301 A US 3854301A
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Images
Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25J—LIQUEFACTION, SOLIDIFICATION OR SEPARATION OF GASES OR GASEOUS OR LIQUEFIED GASEOUS MIXTURES BY PRESSURE AND COLD TREATMENT OR BY BRINGING THEM INTO THE SUPERCRITICAL STATE
- F25J1/00—Processes or apparatus for liquefying or solidifying gases or gaseous mixtures
- F25J1/0002—Processes or apparatus for liquefying or solidifying gases or gaseous mixtures characterised by the fluid to be liquefied
- F25J1/0012—Primary atmospheric gases, e.g. air
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25J—LIQUEFACTION, SOLIDIFICATION OR SEPARATION OF GASES OR GASEOUS OR LIQUEFIED GASEOUS MIXTURES BY PRESSURE AND COLD TREATMENT OR BY BRINGING THEM INTO THE SUPERCRITICAL STATE
- F25J1/00—Processes or apparatus for liquefying or solidifying gases or gaseous mixtures
- F25J1/003—Processes or apparatus for liquefying or solidifying gases or gaseous mixtures characterised by the kind of cold generation within the liquefaction unit for compensating heat leaks and liquid production
- F25J1/0032—Processes or apparatus for liquefying or solidifying gases or gaseous mixtures characterised by the kind of cold generation within the liquefaction unit for compensating heat leaks and liquid production using the feed stream itself or separated fractions from it, i.e. "internal refrigeration"
- F25J1/0035—Processes or apparatus for liquefying or solidifying gases or gaseous mixtures characterised by the kind of cold generation within the liquefaction unit for compensating heat leaks and liquid production using the feed stream itself or separated fractions from it, i.e. "internal refrigeration" by gas expansion with extraction of work
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25J—LIQUEFACTION, SOLIDIFICATION OR SEPARATION OF GASES OR GASEOUS OR LIQUEFIED GASEOUS MIXTURES BY PRESSURE AND COLD TREATMENT OR BY BRINGING THEM INTO THE SUPERCRITICAL STATE
- F25J1/00—Processes or apparatus for liquefying or solidifying gases or gaseous mixtures
- F25J1/02—Processes or apparatus for liquefying or solidifying gases or gaseous mixtures requiring the use of refrigeration, e.g. of helium or hydrogen ; Details and kind of the refrigeration system used; Integration with other units or processes; Controlling aspects of the process
- F25J1/0225—Processes or apparatus for liquefying or solidifying gases or gaseous mixtures requiring the use of refrigeration, e.g. of helium or hydrogen ; Details and kind of the refrigeration system used; Integration with other units or processes; Controlling aspects of the process using other external refrigeration means not provided before, e.g. heat driven absorption chillers
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25J—LIQUEFACTION, SOLIDIFICATION OR SEPARATION OF GASES OR GASEOUS OR LIQUEFIED GASEOUS MIXTURES BY PRESSURE AND COLD TREATMENT OR BY BRINGING THEM INTO THE SUPERCRITICAL STATE
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- F25J3/02—Processes or apparatus for separating the constituents of gaseous or liquefied gaseous mixtures involving the use of liquefaction or solidification by rectification, i.e. by continuous interchange of heat and material between a vapour stream and a liquid stream
- F25J3/04—Processes or apparatus for separating the constituents of gaseous or liquefied gaseous mixtures involving the use of liquefaction or solidification by rectification, i.e. by continuous interchange of heat and material between a vapour stream and a liquid stream for air
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- F25J3/04278—Generation of cold for compensating heat leaks or liquid production, e.g. by Joule-Thompson expansion using external refrigeration units, e.g. closed mechanical or regenerative refrigeration units
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25J—LIQUEFACTION, SOLIDIFICATION OR SEPARATION OF GASES OR GASEOUS OR LIQUEFIED GASEOUS MIXTURES BY PRESSURE AND COLD TREATMENT OR BY BRINGING THEM INTO THE SUPERCRITICAL STATE
- F25J2260/00—Coupling of processes or apparatus to other units; Integrated schemes
- F25J2260/30—Integration in an installation using renewable energy
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25J—LIQUEFACTION, SOLIDIFICATION OR SEPARATION OF GASES OR GASEOUS OR LIQUEFIED GASEOUS MIXTURES BY PRESSURE AND COLD TREATMENT OR BY BRINGING THEM INTO THE SUPERCRITICAL STATE
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- F25J2270/90—External refrigeration, e.g. conventional closed-loop mechanical refrigeration unit using Freon or NH3, unspecified external refrigeration
- F25J2270/906—External refrigeration, e.g. conventional closed-loop mechanical refrigeration unit using Freon or NH3, unspecified external refrigeration by heat driven absorption chillers
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A30/00—Adapting or protecting infrastructure or their operation
- Y02A30/27—Relating to heating, ventilation or air conditioning [HVAC] technologies
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B30/00—Energy efficient heating, ventilation or air conditioning [HVAC]
- Y02B30/62—Absorption based systems
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S203/00—Distillation: processes, separatory
- Y10S203/18—Control
Definitions
- cryogenic fluids e.g., oxygen, absorption refrigeration cycles
- one process comprises the steps of absorbing a refrigerant vapor in a liquid absorbent, increasing the pressure on resultant mixture of said refrigerant and said absorbent, distilling and rectifying the mixture into substantially pure refrigerant vapor and pure absorbent, reducing the pressure on resultant pure liquid absorbent and returning the latter to the absorbing step, cooling and 1 condensing the refrigerant vapor to the liquid state,
- This invention is based upon the employment of one or more absorption refrigeration cycles, so arranged that energy may be recovered from the cycle and allows the production of cryogenic temperatures and the production of useful products.
- This invention is directed to utilization primarily of cycles in which the refrigerant is highly or completely-soluble in the absorbent, such as, but not limited to'the use of a hydrocar-.
- substituted hydrocarbons such as the halogenated hydrocarbons canbe used.
- this invention contemplates the employment of a cascade operation having a series of absorption refrigeration cycles using different refrigerants, such as the use of ethane or propane in the first cycle, ethane or methane in the second cycle, and methane or nitrogen in final cycle. If even lower temperatures are desired, additional cycles using neon, hydrogen or helium as the refrigerants may be employed in lower temperature cycles.
- FIGS. I to X and XV to XVII are schematic flow sheets illustrating the principal features of the various embodiments.
- FIG. I shows the basic absorption refrigeration cycle in a simplified form in which an evaporator-sublimator is used.
- FIG. II shows an embodiment of the absorption refrigeration cycle of the basic system in which. energy is FIG. VII shows a further embodiment in which a gas is Iiquified and in which energy is recovered.
- FIG. VIII shows a system for recovering energy from low temperature source by the use of air as a pressure medium.
- FIG. IX shows a system similar to FIG. VII in which two turbines are employed.
- FIG. X illustrates an embodiment, of the invention in which the refrigeration cycle is combined with a saline water distillation system.
- FIG. XIV is a cross-sectional view of flash distillation vessel of this invention.
- FIGS. XV and XVI are illustrations of this invention in which the power generated is used as a propulsive force.
- FIG. XVII shows the invention as applied to liquefaction of gases.
- the evaporator-sublimator l is connected by a conduit with the absorber 2
- This conduit may be provided with means to produce a lower pressure in the evaporator-sublimator 1 than in the absorber2.
- the column 8 will produce a vapor stream of substantially separated refrigerant at the top of the column and a stream of liquid absorbent relatively free from refrigerant from the bottom of the regenerator 3.
- the absorbent which is hot and under high pressure is returned to the absorber prior to which it must be 'reduced in temperature and pressure to substantially the temperature and pressure in the absorber.
- the pressure may be reduced by passing the liquid through the turbine 7 which will recover part of the energy imparted by the pump 4.
- the liquid absorbent may be cooled, at least in part, by heat exchange with the solution which is being fed to the column 8.
- the heat exchanger 6' is shown provided with coils or the like for effecting this exchange of heat. When the amount of heat in the liquid absorbent is greater than that which can be absorbed by the solution,-the absorbent can be cooled by other means. 7 7
- the substantially pure vapor discharged from the top of the column is passed-through the line 11 to the condenser 12.
- the vapor in condenser 12 As the vapor in condenser 12 is under substantially higher pressurethan exists in the evaporator, it can be condensed to a liquid at a higher temperature than exists in the evaporator-sublimator 1 or the absorber 2.
- the condenser 12 will cool the refrigerant to a temperature below its condensation point at the pressure existing in the condenser. This will discharge a portion of the heat from the system.
- the evaporator-sublimator 1, the absorber 2, the regenerator 3, the column 8, and the condenser 12, are provided with suitable heat exchange means 14, 5, 9,
- this invention prefers the use of refrigerants of the class of methane, ethane, nitrogen, neon, hydrogen and helium with absorbents selected from'the lower boiling hydrocarbons and lower boiling point inorganic fluids,
- FIG. II shows another embodiment of the cycle shown in FIG. I which permits the conversion of some of the thermal energy within the absorption refrigeration system to mechanical energy.
- the gaseous refrigerant discharging from the column 208 of the regenerator 203 is first compressed then heated and expanded to recover part of the energy.
- the gas leaving the column 208 is fed to a compressor 226 through the conduit 211 of a suitable type.
- the compressed vapor is passed through the heat exchanger 219 where the vapors are heated. All or part of this'heat may be supplied by passing the relatively pure absorbent from the regenerator 203 through the heat exchange elements of the exchanger 219.
- the exchanger may also supply heat from external sources.
- the heated and compressed gaseous refrigerant is then expanded through the turbine 220 to convert the thermal energy to mechanical energy.
- the cooled refrigerant at lower pressure is then passed to the 'condenser 212 where it is cooled to condensation point.
- the liquid is then passed through the pressure reduction means 213 and fed into the evaporator-sublimator 201.
- the vapors from the evaporator-sublimator 201 are passed by-mechanical inducement in pump 205 to I the absorber 202 and mixed with absorbent which has passed through the heat exchangers 219 and 206 and turbine 207.
- the solution from the absorber 202 is pumped by pump means 204 through the heat exchanger 206 to the column 208.
- the pure absorbent from the regenerator 303 is passed through the heat exchange means 319 and supplies part of the heat to the refrigerant which has been compressed by pump 326.
- the partially cooled absorbent then is passed to the heat exchanger 306 and then through the turbine 307 to the absorber 302.
- the absorbent has been partially cooled before arriving at the 7 heat exchanger 306, it supplies only a part of the heat necessary for conditioning the mixture or solution of refrigerant and absorbent to be fed into the column. Additional heat can be supplied to the mixture by cooling the vapors in the heat exchange means 327.
- the heat for the separation of the mixture is supplied by the heat exchange means 309, and the refrigerant is vaporized by the heat supplied in the evaporatorsublimator 301 by the heat exchange means 314. Heat is removed from the condenser by the heat exchange means 316, and the absorber by heat exchange means 305. It is to be understood that the area of heat exchange surfaces in the regenerator 303, the condenser 312, the heater 306, the cooler 323, the absorber 302, and the heater 319, will be selected to give the transfer appropriate to steady operation.
- FIG. IV illustrates a cycle which is an embodiment of the basic cycle and which is designed to produce very low temperatures in single cycle. This arrangement materially reduces the amount of energy required to generate a given refrigerating effect.
- the values are given for a cycle using methane as the refrig-- erant and propane as the absorbent.
- the evaporatorsublimator 401 is supplied'with about 0.45 pounds of methane per second at a temperature of about 163 R. and discharges the vapors at about 135 R. at a pressure of 0.1354 psia.
- the vapors are passed to the absorber 402 and are mixed with about 1.1 pounds per second of propane having a'temperature of about 154.5 R.
- the pressure in the absorber 402 is about 0.0967 psia.
- the solution of methane in propane is discharged from the absorber at the rate of about 1.6 pounds per second and at a temperature of about 153 R.
- the solution passes to a heat exchanger corresponding to the heat exchanger 6 of FIG. I.
- This stream is supplied at the rate of 0.19 pounds per second.
- the solution is discharged from the heat exchanger 406 at the rate of 1.79 poundsper second at a temperature of 155 R.
- the solution is then heated in heat exchanger section 406 to about 374 R, by the stream of propane returning to the absorber.
- the solution is pressurized by the 7 pumps 404 and 404' to a pressure of about 600 psia and is introduced into column 408 of the regenerator or separator 403.
- the regenerator 403 is heated by the coil 409 which received a heating medium at 658 R.
- the separated propane leaves the regenerator at a weight of 1.144 pounds per second at a temperature of 653 R.
- the stream of propane Before entering the heat exchanger 406, the stream of propane is cooled by passing through heat exchangers 427 and 428.
- the stream of propane is cooled by fluid passing through coils 421 and 422 to a temperature of about 449 R.
- the methane leaves the top of the column 408 at the rate of about 5.47 pounds per second and is transferred to heat exchanger 419 where the methane is cooled by fluid in the coil 420.
- the methane leaving the column 408 is at about 340 R. and is cooled to 336 R. in the heat exchanger 419.
- a major amount of the methane amounting to about 4.82 pounds per second is returned to the column 408 where it serves as reflux.
- the minor portion of the methane amounting to about 0.64 pounds persecond is transferred to the condenser 412.
- the methane In condenser 412, the methane is cooled and liquified to a temperature about 229 R. and the stream is passed to the heat exchanger 406'.
- the major portion of the condensate amounting to 0.45 pounds per second passes through the coil 426 and is passed through the pressure reducing means 413 into the absorber 401.
- a minor portion of the con single operation it should be noted that this operation requires only the addition of mechanical energy to operate the pumps 404 and 404. In this example, the heat supplied was at 658 R. or 199 F. which would be normally considered as waste heat.
- FIG. V illustrated one manner in which it contemplated to arrange two absorption refrigeratingcycles of this invention, in a cascade manner so as to utilize maximum percentage of the energy supplied to the system.
- the Figure also illustrates how energy can be recovered in a cascade system.
- the vapors of refrigerant are passed from coils in condensers 512 and 512' and then lead into the columns 508and 508'.
- the vapors from the columns 508 and 508 are passed through their respective heat exchangers 520 and 520.
- the vapors are heated in these exchangers by heating fluid supplied to coils 524 and 524'. While the connection is not shown on the drawing for passing the returning absorbent from the regenerators 503 and 503to the heat exchangers 520 and 520', it is to be understood that a portion, at least of the heat supplied to the vapors, maybe derived from these sources as shown in FIG. Ill.
- the separate streams of .vapors heated in exchangers 520 and 520' are expanded by passing them through the corresponding turbines 523 and 523.
- the vapors from the turbines are then fed to the condensers 512 and 512' respectively and the energy in the liquid refrigerant recovered in the pressure reducing means 513 and 513' and the liquids passed to the evaporator-sublimators 501 and 501'.
- FIG. V the two cycles are shown as being in heat exchange relation by having a'heat transfer means 530 removing heat from condenser 512 and supplying the same heat to the regenerator 503'.
- Another heat transfer means 531 is shown for removing heat from the condenser 512 and absorber 502- and supplying this heat to the evaporator 501.
- the turbines 507 and 507' perform the same functions as the corresponding parts in FIG. I, as do the heat exchangers 505, 509, 510 and 510'.
- the available heat in one portion of the system can be transferred to another location in the same cycle where the difference in temperature is sufficient to effect a worthwhile heat exchange.
- the area of the heat exchange surfaces will be selected to give the desired transfer of heat.
- the individual features may be combined when ever a significant saving of heat or energy will be effected.
- FIG. VI illustrates a generic arrangement for the liquification of a gas such as air, using the heat sink of an individual cycle or a plurality of cycles to remove the heat from the air.
- a gas such as air
- FIG. VI illustrates a generic arrangement for the liquification of a gas such as air, using the heat sink of an individual cycle or a plurality of cycles to remove the heat from the air.
- the details of the refrigeration cycles have been omitted and are indicated merely by the cooling coils in the heat exchangers 642 and 644.
- Atmospheric air enters through a conduit 640 and is passed through the turbine 64] into a region of lower pressure and is passed through the heat exhangers 642 and 644 of the absorption refrigeration cycle.
- the cooling of the air is provided by substantially isentropic expansion in the turbine and by heat exchange with the heat sinks of the refrigeration evaporators in'the heat exchangers 642 and 644, where the air is condensed to liquid.
- the system' may be provided with known means to remove water vapor and carbon dioxide, to avoid fouling of the heat exchanger surfaces.
- the liquid air is discharged from the heat exchanger 644 into conduit 645 and may be drawn off as a product by conduit 646.
- the liquid air may be I fed to separator 647,'which may be of known construction, e.g., a rectification column which will separate the liquid air into its components. Frequently, only nitrogen and oxygen will be separated, but the invention contemplates the recovery of the minor constituent gases of the atmosphere, e.g., argon, neon, helium, krypton, hydrogen xenon, ozone and radon, if desirable.
- the carbon dioxide in the air may also be recovered in the process.
- the oxygen and nitrogen may be drawn off at 648 and 649, if desired, to use the separated element as such and may besupplied to other processes.
- the liquid air from conduit 645 may be passed to pump 661 where the fluid is pressurized. and then passed to coil 651.
- the oxygen passes to pump 662 and coil 652, and the nitrogen to pump 663 and coil 653 of heat exchanger 650.
- the respective streams can then be passed, if desired, to turbines 657, 658 or 659 respectively.
- the product may be recovered by vessel 660.
- This Figure illustrates the many ways in which the ab-' sorption refrigeration system can be used commercially to recover energy and to supply liquid, air, oxygen, nitrogen, or the rare gases to industrial processes. Since '10 the process of refrigeration as described in this specification does not require the consumption of large amounts of energy, it provides these materials in an economical manner.
- the heat exchanger 650 may also serve to transfer heat between two or more of the streams.
- the coil 65] which receives liquid air may serve to further cool other streams, or may be further cooled by the other streams.
- the coil 654 is indicated as a separate heat exchange means for an independent heat transfer medium to supply heat to or to remove heat from the exchanger 650, and may serve to transfer heat between the liquid air, the nitrogen or oxygen and the absorption refrigeration cycle. There may be a plurality of these means as desired.
- the vessel 660 into which the gases are individually collected may serve as a heat sink for the absorption refrigeration system or as an independent cooling means. 5
- FIG. VII illustrates the basic system for recovering energy using a low temperature in the cycle with air as the energy transfer medium with liquifaction of the air.
- the lowest temperature will be substantially the temperature of liquidair, and the highest temperature normally contemplated is that available from waste heat. While it is preferred to use waste heat as the source of the highest temperature in the cycle, it is,
- a cascade refrigeration system as-illustrated in FIG. V is indicated by the block 770 in the drawing. This system is provided with heat transfer. means 771 to remove heat from the energy producing system. While only a single means 771 is indicated in the drawing it is to be understood that this means may be composed of a plurality of separate connections for transferring heat at different temperatures between the systems.
- the heat exchanger which is shown diagrammatically, is supplied with a gas, usually air, which is condensed by the cooling effect of the transfer means to a liquid. While air is usually the gas employed, nitrogen or other gases can be used to avoidthe risk of combustion and oxidation.
- the liquid air from the heat exchanger 772 is passed to the pump 773 which increases the pressure on the liquid. The change in pressure is usual quite significant.
- the liquid at the higher pressure is circulated through the heat exchangers 774 and 775 and converted to gas at high pressure and, temperature and then is expanded through the turbine 776.
- the air leaving the turbine is cooled in heat exchanger 774 by heat exchange with the liquid air from the pump 773.
- the cooled air is then fed to the condenser or heat exchanger 772 completing the, cycle.
- This Figure shows a simplified energy recovery sys- A est temperature in the proposed system is near absolute zero the efficiency of the system is high.
- the maximum Ill efficienty of a steam system is low since the temperature of condensation is high.
- the air may be heated in heater 775 by heat from any source.
- FIG. VIII illustrates a more developed system for recovering energy.
- This Figure employs the basic energy system set forth in FIG. VII.
- the absorption refrigeration system is indicated by the block 870.
- This absorption refrigeration system can be like the one shown in FIG. V but the details of the system have been omitted for the purpose of clarity.
- the refrigeration system is shown as removing heat from the energy recovery system by the heat transfer means 871 associated with the condenser or heat exchanger 872.
- the liquid gas which will be, hence forth referred for convenience as liquid air, is passed from the condenser 872 to the first pump 873 which increases the pressure of liquid air to about 50 psia.
- the pressurized liquid air is passed through the heat exchangers 874 and 874' and is heated by the air leaving the turbines.
- the liquid air is then pressurized by the pump 873 to a very high pressure such as 3500 psia., and is fed to the heat exchanger 874"; In this heater, the liquid air is vaporized and converted into gas at high pressure and much higher temperature.
- the hot gas is further heated in heat exchanger 875 and introduced into the turbine 876.
- the air as discharged from turbine 876 is reheated to about the original high temperature by the reheater 875' and is expanded through a second turbine 876'.
- the gas at lower pressure and temperature is reheated to about the original high temperature in reheater 875" and is expanded'through the third turbine 876".
- the air is then passed through the heat exchanger 874" and to the condenser 872 after passing through the cooler 890 and the heat exchangers 874 and 874.
- this system can be arranged to circulate air at the rate of one pound per second through the cycle. If the pressure in the condenser is maintained at atmospheric pressure, the temperature in the condenser will be about l42 R.
- the liquid air is pressurized to about 50 psia. and passed through heat exchangers 874' and 874 and the temperature raised to about 165 R.
- the pump 873 raises the pressure to about 3,500 psia. and the temperature is raised to about 202 R.
- the liquid air is passed through the heaters 874 and 875 and is converted to gas at 700 R. (240 F.).
- the hot air is cooled in passing through the turbine 876 to 437 R. and the pressure is reduced to about 565 psia.
- the air is returned to the temperature of 700 R.
- turbine 87 6' the temperature is dropped to 473 R. and the pressure to about 91 psia.
- the air is reheated to about 700 R.
- the expansion in turbine 876" drops the temperature of the air to 473 R.
- the liquid air flowing from the condenser 872 is pressurized by the pump 873 (point 2 on the chart) and is returned in indirect heat exchange in heater 874 to absorb part of the latent heat of the condensing air.
- This transfer of energy is possible with air, as air is essentially a binary mixture of oxygen and nitrogen, and the dew point temperature is approximately 55 F. higher than its bubble point.
- the heat exchanger 874 warms the liquid air to slightly below its saturation point (point 4 on the chart).
- the liquid is pressurized by pump 873' to the pressure at turbine inlet (point 8on the chart).
- the liquidat high pressure is vaporized in the heat exchanger 875. In this heat exchanger, the highest temperature in the cycle is reached.
- the temperature shown can readily be reached by employing low quality thermal energy, such as waste heat. None in this disclosure should be construed as preventing the use of higher temperatures which can be obtained from other heat sources.
- FIG. IX illustrates another embodiment of the'invention for the recovery of energy, preferably using the absorption refrigeration system as a means for establishing the necessary temperature differential.
- the air is cooled in the heat exchangers tion of the liquid air leaving the. pump 873; 3, 4 and 5,
- ure 970 indicates an absorption refrigeration system and97l indicates a heat transfer means for transfering heat from the power recovery system to the heat sinkof the refrigeration cycle.
- This system includes a condenser 972 for liquifyinga gas such as air.
- the liquid air is pressurized by the pump 973 and is heated by the heat exchanger 974.
- the heating medium is the air being cooled and condensed.
- the pressurized and heated liquid air is vaporized in the heat exchanger 975 and is introduced into the turbine 976 and then reheated in reheater 975' and passed into turbine 976'. This turbine discharges the air at the pressure of the condenser.
- This Figure shows an arrangement generally corresponding to the system .of FIG. VIII, but in which the construction has been simplified. This Figure shows an arrangement which will allow a substantial recovery of power with a lower plant investment.
- the actual selection of the number of turbines and the number of reheaters will depend upon an economic balance between the cost of equipment and the value of the power drived.
- FIG. X illustrates the recovery of pure water by the use of a low grade heat source.
- the cost of the power required to vaporize the water has been the cost of the power required to vaporize the water.
- Another problem has beenthe scaling of the water in the heating vessels.
- the utilization of the absorption refrigeration systems of this invention will overcome some of these previous difficulities.
- the evaporator of the absorption refrigeration system is indicated as 1001, the refrigerant absorber as 1002, the pump for the solution of refrigerant and absorbent as 1004, the regenerator as 1003 and the column as 1008.
- the vapors of the, refrigerant are passed to the heater 1019 and are heated by indirect heat exchange with theabsorbent from the regenerator 1003.
- the heated vapors are then expanded through the turbine. 1020, to recover energy and to cool the vapors.
- the vapors are condensed in condenser 1012 and the liquid refrigerant is passed through the pressure reduction means 1013 to the evaporator 1001.
- the refrigeration system thus far disclosed is similar to that shown in FIG. IV.
- the condenser 1012 includes a heat exchanger element-102l through which is passed the water to be distilled.
- the refrigerant and the pressure of condensation are selected so that the heat of the condensing vapors heats the water to be distilled.
- the warmed water is then passed to the heat exchange element 1006' in the heat exchanger 1006, and the water is further heated by the absorbent returning to the absorber 1002 from the regenerator 1003.
- the hot water isthen fed into the distillation system.
- the distillation system comprises a series of flash chambers which utilize the latent heat in the water to vaporize a portion of the water.
- the hot water is introduced in the first flash chamber 1080, and a portion of the water flashed into steam.
- the steam is fed through the heat exchange means 1082 in the second flash,
- the vapors from the final flash chamber and the condensate from the heat exchanger 1082 are fed into the condensing chamber 1083.
- This chamber is cooled by heat exchange element 1084 through which is circulateda heat exchanger medium which also is passed through the element 1014 of the evaporator 1001.
- the non-condensible gases in the saline water are removed from the distillation system by the ejector 1086.
- the evaporator 1001 which is heated by the condensing water vapor in the condenser 1083, will maintain a minimum pressure and temperature in the water vapor condenser.
- the unevaporated water or waste brine from the final distillation stage is discharged through the heat exchangemeans 1087 in the refrigerant condenser 1012 or through the heat exchange means 1088 in the refrigerant absorber 1002, to remove the heat of these elements.
- the distilled water is passed through the heat exchanger means 1089 in the refrigerant condenser 1012 or through the heat ex-- change means 1091 in the absorber 1002 or through both.
- FIG. X demonstrates the application of absorption refrigeration system ofthis invention using a low temperature heat source to produce energy and to performuseful chemical engineering unit process operations. While this example shows the application of the process ofthis invention to the distillation of water, it is apparent that other liquids could be distilled in a similar manner. Furthermore, the temperature differential available from the absorption refrigeration cycles of this invention can be used in other unit processes requiring temperature changes. For example, water could be purified by freezing rather than by distillation. The invention could also be used to dehydrate materials as by freeze drying since the invention can produce both low temperature and low pressure.
- FIG. XI shows the construction of a preferred form of the evaporator-sublimator of this invention.
- the figure is a cross section through the vessel constituting the evaporator-sublimator.
- Thevessel is normally provided with insulation about the walls.
- the interior of the vessel is divided into a liquid receiving section 1101 and a vapor section 1103 with a porous plate 1 102 separating the section from each other.
- the liquid to be vaporized is introduced into the section 1101 by the pipe 1104.
- the vapor is removed'from section 1103 by the pipe 1105.
- This pipe is designed to maintain the pressure in the section 1103 at a desired level.
- the pipe 1105 may include a fan, if necessary, to maintain the desired pressure.
- the porous plate 1102 which serves as a partition, is formed of an open cell 'material such as porous brick or stone or metal which will permit the slow passage of the liquid through the partition.
- the partition includes a heat exchange means 1114 which will supply the heat necessary to vaporize the liquid. This heat exchange means serves as the heat sink in the refrigeration cycle.
- the liquid When the pressure in the chamber is above the triple point of refrigerant, the liquid will ooze through the plate and be heated by the heat exchange means and will evaporate into the chamber 1102. This will occur before the system has reached the triple point pressure at the time the system is being started up or the system can be operated under these conditions as desired.
- FIG. XIII shows a vapor separator particularly adapted to be used in the flash distillation-chambers of the system shown in FIG. Xl While particularly adapted for this type of system, the separator can be used in any distillation system benefitted by little or no entrainment of the distilland in the vapor.
- 1301 indicates the vessel for receiving the liquid to be distilled through the pipe 1302 and discharging the vaporthrough the pipe 1303.
- This baffle means includes a shaft 1305 which is mounted for rotation about an axis. A series of turbine blades 1307 are secured in an inclined position to the shaft so that the passage of vapor towards the outlet pipe 1303 cause the shaft to rotate.
- the heat sink of an absorption refrigeration system is indicated by the block 1570.
- the power generating system receives air from the atmosphere at 1560-The entrance may be in the form of a scoop, taking advantage of the vehicles forward motion to increase the flow of air.
- the entering air is passed to the precooler 1571 and is conveyed from there to the turbocompressor 1572.
- the compressed air passes through the heat exchange means 1573 in the pre- "cooler.
- the compressed air is fed to theturbine 1574 and there expanded.
- the cooled air is then passed into the condenser 1577, in which it is further cooled by supplying heat to the refrigeration cycle, and is condensed to a liquid.
- FIG. XVII illustrates one absorption refrigeration cycle of a cascade system.
- the absorber 1702 feeds the solution of a gas such as hydrogen in a liquid hydrocarbon to the pump 1704 and hence to the heat exchanger 1706 and to the column 1.708 of the regenerator or separator 1703.
- the heat necessary to separate the gas from the absorbent is preferably supplied bythe condenser of another cycle in the cascade arrangement by means 1709.
- the gas is then supplied to 'a heat exchanger 1712.
- This exchanger is arranged to remove heat from the gas and supply this heat to an evaporator of another cycle in the cascade system.
- This heat exchanger also includes another heat exchange element 1721.
- a refrigeration process comprising the steps of:
- the refrigerant is selected from the group consisting of nitrogen, hydrogen, neon, helium and hydrocarbon having a saturationpressure between that of butane and methane;
- the absorbent is a liquid having a freezing point below the temperature of the process and selected from the group consisting of a hydrocarbon liquid and an inorganic liquid.
- a process for the recovery of energy and refriger ation comprising the steps of: r absorbing a refrigerant vapor in a liquid absorbent; increasing the pressure on the resultant mixture of refrigerant and absorbent; distilling and rectifying the mixture into substantially pure refrigerant vapor and pure absorbent;
Abstract
For the development of power and/or the production of cryogenic fluids, e.g., oxygen, absorption refrigeration cycles are employed. For example, one process comprises the steps of absorbing a refrigerant vapor in a liquid absorbent, increasing the pressure on resultant mixture of said refrigerant and said absorbent, distilling and rectifying the mixture into substantially pure refrigerant vapor and pure absorbent, reducing the pressure on resultant pure liquid absorbent and returning the latter to the absorbing step, cooling and condensing the refrigerant vapor to the liquid state, reducing the pressure upon the liquid refrigerant to below the triple point of the refrigerant to produce solid refrigerant, sublimating the solid refrigerant to the vapor state, and passing resultant refrigerant vapor to the absorbing step at a rate that maintains the pressure below the triple point.
Description
[ Dec. 17, 1974 1 CRYOGENIC ABSORPTION CYCLES [76] Inventor: Ellis P. Cytryn, 900 W. Rt. 70, Marlton, NJ.
[22] Filed: June 11, 1971 [21] App1.No.: 152,332
[52] US. Cl 62/101, 60/36, 62/9, I 62/112, 62/335, 62/467, 62/476, 203/D1G. 17 [51] Int. Cl. F25b 15/00 [58] Field of Search 62/46, 101, 102, 112, 467, 62/476; 60/36 [56] References Cited UNITED STATES PATENTS 1,982,672 12/1934 Koenemann 62/101 2,667,764 2/1954 Turner 62/101 2,751,748 6/1956 Bach] 50/36 3,041,853 7/1962 Harwich 62/467 3,145,304 7/1965 Stern et a1. 60/36 3.170.303 2/1965 Rannenberg.'.. 62/467 X 3,197,973 8/1965 Rannenberg... 62/467 3,483,710 12/1969 Bearint 62/101 X 3,505,810 4/1970 Mamiya 62/467 X OTHER PUBLICATIONS Refrigeration and Air Conditioning, W. F. Stoecker,
McGraw-Hill, 1958, p. 37.
Primary Examiner-William F. O'Dea Assistant Examiner-Peter D. Ferguson Attorney, Agent, or FirmMillen, Raptes & White ABSTRACT For the development of power and/or the production of cryogenic fluids, e.g., oxygen, absorption refrigeration cycles are employed. For example, one process comprises the steps of absorbing a refrigerant vapor in a liquid absorbent, increasing the pressure on resultant mixture of said refrigerant and said absorbent, distilling and rectifying the mixture into substantially pure refrigerant vapor and pure absorbent, reducing the pressure on resultant pure liquid absorbent and returning the latter to the absorbing step, cooling and 1 condensing the refrigerant vapor to the liquid state,
reducing the pressure upon the liquid refrigerant to below the triple point of the refrigerant to produce solid refrigerant, sublimating the solid refrigerant to the vapor state, and passing resultant refrigerant vapor to the absorbing step at a rate that maintains the pressure below the triple point.
10 Claims, 17 Drawing Figures 1 m l w 324 w, 323 320 M 4 Jan 32s v 327 '53 3 2 303 a, 3'3 306 g g PAIENTEU m1 1W4 3,854,301
snsmura I H E3 1 +4 FIG. I i i 6 4 7 '5\ q P/B/W 2 "I l FIG.
INVENTOR ELLIS P. CYTRYN BY mzzw WMZM ATTORNEYS PATENTED 3.854.301
INVENTOR ELLIS P. CYTRYN BY m Q z/Q J/M AT TOR NEYS PATEHIEB DEC 1 71974 SHEET 7 BF 8 Pmmw 3.854.301
SHEET 80F 8 FIG. m
m \/\/V\ -|67O 4682 468i 672 I 60 WW l |ss4- I MM new 673/ I683 woe 17127 703x :B -|?2| {L09 lg was I um i V l 9 La I702 INVENTOR FIG. XIEE ELLIS P CYTRYN ATTORNEYS processes for the development of powerand the production of useful industrial products, such as liquid air,
liquid oxygen, liquid nitrogen and the development of cryogenic temperatures and is based upon new arrangements and cycles of absorption refrigeration.
BACKGROUND OF THE INVENTION Since the development of the steam engine in the Seventeenth Century, the common source of energy for mans use has been the combustion of fossils fuels at high temperatures. This burning of fossils fuel in either a furnace or in an internal combustion engine has resulted in the pollution of the atmosphere with both the products of combustion and with heat, and the removal of heat in the development of power has resulted in the thermal pollution of large bodies of water. In a high temperature energy system, such as the steam turbine, the working fluid water is first evaporated at high pressure and then expanded in the turbine and finally condensed to liquid 'at temperatures above the ambient temperature. The heat rejected is usually discharged into a river or lake. The use of water as the working fluid introduces the exceedingly high heat of vaporiza- SUMMARY OF THE INVENTION The present invention offers techniques which permit the reduction of polluting effect of the prior process for converting heat into power, as these techniques utilize heat which has been wasted. One embodiment of the present invention begins with air at ambient temperature and pressure and liquifies the air at subatmospheric pressure and temperature and recovers the energy from the air. As a feature of this process the air can be heated during the process by what is now considered to be wasteheat, and the energy of this waste heat recovered. The present invention teaches the recovery of useful work from waste heat and from solar energy.
This invention is based upon the employment of one or more absorption refrigeration cycles, so arranged that energy may be recovered from the cycle and allows the production of cryogenic temperatures and the production of useful products. This invention is directed to utilization primarily of cycles in which the refrigerant is highly or completely-soluble in the absorbent, such as, but not limited to'the use of a hydrocar-.
bon, such as methane, in'solution of ahigher boiling hydrocarbon, such as ethane or propane. Other combinations such as ethane in solution in propane or propane in butane are illustrative. Further examplesof useful combinations are solutions of nitrogen in methane, or ethane, or hydrogen in methane. Any hydrocarbon whose saturation pressure and temperature relationships are between that of methane and butane is acceptable. It is apparent that substituted hydrocarbons such as the halogenated hydrocarbons canbe used.'In order to secure the maximum differences in temperatures, this invention contemplates the employment of a cascade operation having a series of absorption refrigeration cycles using different refrigerants, such as the use of ethane or propane in the first cycle, ethane or methane in the second cycle, and methane or nitrogen in final cycle. If even lower temperatures are desired, additional cycles using neon, hydrogen or helium as the refrigerants may be employed in lower temperature cycles.
It is thus an object of this invention to provide a-system in which very low cryogenic temperatures can be obtained with the energy for the system being derived from waste heat.
It is a further object of the invention to recover the latent energy from low temperature heat sources such as waste heat from power plants or from solar energy.
It is a further object of this invention to recover pure gases from air using low grade heat as the source of the energy needed to separate the pure gas from air.
It is a further object of this invention to recover pure water from saline and impurewaters using an absorption refrigerationcycle to supply the energy to separate the pure water from the brine.
It is a further object of this invention to recover energy from fluids which are being liquified.
It is a further object of 'this invention to produce a low temperature process in which the refrigerant is sublimed.
It is still a further object of this invention to provide an evaporator-sublimator which has a porous partition.
It is afurther object of the invention to provide a power system which'can be utilized for the propulsion of vehicles in which the amount of heat discharged is substantially reduced and in which the efficiency is materially increased.
Further objects and advantages of the present invention will become apparent upon further study of the specification and claims.
BRIEF DESCRIPTION OF THE DRAWINGS The more specific objects and advantages of this invention will be more readily apparent from the-ensuing description-wherein reference is made to the accompanying drawings illustrating the preferred embodiments of the invention.
In the drawings,
FIGS. I to X and XV to XVII are schematic flow sheets illustrating the principal features of the various embodiments.
FIG. I shows the basic absorption refrigeration cycle in a simplified form in which an evaporator-sublimator is used.
FIG. II shows an embodiment of the absorption refrigeration cycle of the basic system in which. energy is FIG. VII shows a further embodiment in which a gas is Iiquified and in which energy is recovered.
FIG. VIII shows a system for recovering energy from low temperature source by the use of air as a pressure medium.
FIG. IX shows a system similar to FIG. VII in which two turbines are employed.
FIG. X illustrates an embodiment, of the invention in which the refrigeration cycle is combined with a saline water distillation system.
FIG. XI is cross-sectional view through an evaporator-sublimator of this invention.
FIG. XII is a cross-sectional view of another embodiment of an evaporator-sublimator of this invention.
FIG. XIII is a chart showing the conditions during a power recovery cycle of this invention.
FIG. XIV is a cross-sectional view of flash distillation vessel of this invention.
FIGS. XV and XVI are illustrations of this invention in which the power generated is used as a propulsive force.
FIG. XVII shows the invention as applied to liquefaction of gases.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The absorber 2 receives the vapor from the evaporator-sublimator and also receives absorbent from the regenerator 3. The absorber 2 can be provided with known means for effecting contact between the vapor and the liquid. The pressure in the absorber will be maintained below the saturation pressure for the refrigerant in the absorbent. The solution which is a mixture of the refrigerant and absorbent is transferred by the pump 4 to the regenerator 3.
As the refrigerant and absorbent used in the preferred embodiments of this invention may have close boiling points, it is generally necessary to have a distillation process embodying a rectification system to sep-- arate the substantially pure refrigerant from the relatively pure absorbent. While it is generally contemplated to employ a rectification column, there are some FIG. 1 illustrates the basic refrigeration cycle em- I frigerant in a heat sink by the removal of heat from another body, followed by the absorption of the refrigerant in an absorbent to form a liquid solution. The solution is transferred to another place and heated to sepa rate the refrigerant from the absorbent followed by the condensation and return of the refrigerant to the evaporator. The system preferably is operated with the separator and condenser at a higher pressure than the absorber. While it is possible to introduce a third fluid to the refrigerant and absorbent solution to produce transfer of the fluids by diffusion without the requirements for mechanical energy inputs, this invention contemplates a continuous system in which mechanical energy is used to transfer the solution of refrigerant in absorbent from the zones of lower pressure to the zones of higher pressure. This energy can be recovered,-at least in part from the absorbentand the refrigerant as they move from the zones of higher pressure to the zones of lower pressure. In order that substantial refrigerating effects are obtained and that there be available substantial recovery of energy, it is contemplated to have substantial difference in pressure between these zones.
In FIG. I, the evaporator-sublimator l is connected by a conduit with the absorber 2 This conduit may be provided with means to produce a lower pressure in the evaporator-sublimator 1 than in the absorber2. The
provision of such means is particularly desirable when combinations of refrigerant and absorbent which can be separated by simple distillation.
The regenerator-or separator 3 includes a rectification column 8 having a.cooling coil 10 to provide the necessary reflux for separation. This column can be of any well-known construction and can be either a plate column or a packed column. The regenerator will also be provided with a heating coil 9. This coil will ordinarily supply the major part of theheat used in the process and will generally reach the highest temperature in the cycle. v
In accordance with good distillation practice, the solution of refrigerant and absorbent will be introduced into the column at an-optimized point. The composition of the mixture introduced at the point will approximate the composition of the mixture in the column at the point of introduction. The preferred mode of heating the mixture of the refrigerant and absorbent before it is introduced into the column will be described later.
The column 8 will produce a vapor stream of substantially separated refrigerant at the top of the column and a stream of liquid absorbent relatively free from refrigerant from the bottom of the regenerator 3. The absorbent which is hot and under high pressure is returned to the absorber prior to which it must be 'reduced in temperature and pressure to substantially the temperature and pressure in the absorber. The pressure may be reduced by passing the liquid through the turbine 7 which will recover part of the energy imparted by the pump 4. The liquid absorbent may be cooled, at least in part, by heat exchange with the solution which is being fed to the column 8. The heat exchanger 6' is shown provided with coils or the like for effecting this exchange of heat. When the amount of heat in the liquid absorbent is greater than that which can be absorbed by the solution,-the absorbent can be cooled by other means. 7 7
The substantially pure vapor discharged from the top of the column is passed-through the line 11 to the condenser 12. As the vapor in condenser 12 is under substantially higher pressurethan exists in the evaporator, it can be condensed to a liquid at a higher temperature than exists in the evaporator-sublimator 1 or the absorber 2. The condenser 12 will cool the refrigerant to a temperature below its condensation point at the pressure existing in the condenser. This will discharge a portion of the heat from the system.
The condensed refrigerant is passed as a liquid through the pressure reducing means 13. This can be a simple pressure reducing valve or orifice. However,
it is preferred to use a device which will recover at least some of the energy available upon the release of pressure. This device will normally take the form of a turbine of known construction, but any other form of device which will recover the energy can be used. It is to be understood that Whenever the term turbine is used to described a means for recovering energy by pressure reduction, any similar expansion engine is included.
The evaporator-sublimator 1 is provided with a heat exchange means 14, which supplies the heat necessary to vaporize the refrigerant and is cooled to approach the lowest point in the cycle. The evaporatorsublimator 1 is preferably of the construction shown in more detail in FIGS. XI and XI], and will be described later. This evaporator-sublimator is designed to permit the conversion of the refrigerant to vapors by either sublimation or evaporation. The liquid refrigerant from the pressure reduction means 13 is fedinto the first compartment 15 of the evaporator-sublimator 1. This compartment is separated from the vapor section 17 by a porous plate 18 through which passes the heat exchange means 14. The liquid in compartment 15 is at a slightly higher pressure than exists in the vapor section 17, and thereby oozes through the porous partition.
When the pressure in the compartment 17 is below the triple point, the refrigerant will freeze as it is passed through the porous partition. The frozen refrigerant will thus block the pores in the plate and preventfurther flow. The heat exchange means 14 will then supply the heat necessary to sublime the refrigerant. At this stage the heat exchanger 14 constitutes the heat sink of I the process. This manner of operation requires that the pressure in the vapor section be below the triple point for the refrigerant. To maintain this pressure may require the positive removal of vapor from the section 17 by mechanical means.
If the pressure of the refrigerant in the section 17 is not belowthe triple point of the refrigerant, the liquid refrigerant will ooze through the porous plate and be evaporated by the heat from the heat exchange 14.
The evaporator-sublimator 1, the absorber 2, the regenerator 3, the column 8, and the condenser 12, are provided with suitable heat exchange means 14, 5, 9,
10 and 16, respectively. The heat exchanger 14'will supply the heat necessary to vaporize the liquid refrigerant and will cool the fluid circulating therein to the lowest temperature in the system. The heat exchangers 5, l0 and 16 will abstract heat from the system.
As this invention prefers the use of refrigerants of the class of methane, ethane, nitrogen, neon, hydrogen and helium with absorbents selected from'the lower boiling hydrocarbons and lower boiling point inorganic fluids,
cording to the needs of the process and the cooling medium available. In some instances, water at ambient temperature can be used, and in others the heat can be rejected through a suitable heat exchanger directly to the ambient atmosphere. I I
FIG. II shows another embodiment of the cycle shown in FIG. I which permits the conversion of some of the thermal energy within the absorption refrigeration system to mechanical energy. In this modification, the gaseous refrigerant discharging from the column 208 of the regenerator 203, is first compressed then heated and expanded to recover part of the energy. The gas leaving the column 208 is fed to a compressor 226 through the conduit 211 of a suitable type. The compressed vapor is passed through the heat exchanger 219 where the vapors are heated. All or part of this'heat may be supplied by passing the relatively pure absorbent from the regenerator 203 through the heat exchange elements of the exchanger 219. The exchanger may also supply heat from external sources.
The heated and compressed gaseous refrigerant is then expanded through the turbine 220 to convert the thermal energy to mechanical energy. The cooled refrigerant at lower pressure is then passed to the 'condenser 212 where it is cooled to condensation point. The liquid is then passed through the pressure reduction means 213 and fed into the evaporator-sublimator 201. The vapors from the evaporator-sublimator 201 are passed by-mechanical inducement in pump 205 to I the absorber 202 and mixed with absorbent which has passed through the heat exchangers 219 and 206 and turbine 207. The solution from the absorber 202 is pumped by pump means 204 through the heat exchanger 206 to the column 208.
Referring to the embodiment illustrated in FIG. III, the pure absorbent from the regenerator 303 is passed through the heat exchange means 319 and supplies part of the heat to the refrigerant which has been compressed by pump 326. The partially cooled absorbent then is passed to the heat exchanger 306 and then through the turbine 307 to the absorber 302. As the absorbent has been partially cooled before arriving at the 7 heat exchanger 306, it supplies only a part of the heat necessary for conditioning the mixture or solution of refrigerant and absorbent to be fed into the column. Additional heat can be supplied to the mixture by cooling the vapors in the heat exchange means 327.
The heat for the separation of the mixture is supplied by the heat exchange means 309, and the refrigerant is vaporized by the heat supplied in the evaporatorsublimator 301 by the heat exchange means 314. Heat is removed from the condenser by the heat exchange means 316, and the absorber by heat exchange means 305. It is to be understood that the area of heat exchange surfaces in the regenerator 303, the condenser 312, the heater 306, the cooler 323, the absorber 302, and the heater 319, will be selected to give the transfer appropriate to steady operation.
The features which are specifically shown in FIGS. I, II and III can be combined or modified by the features of each other and can be used in connection with auxil iary equipment as is well-known in the art.
FIG. IV illustrates a cycle which is an embodiment of the basic cycle and which is designed to produce very low temperatures in single cycle. This arrangement materially reduces the amount of energy required to generate a given refrigerating effect. In this example the values are given for a cycle using methane as the refrig-- erant and propane as the absorbent.
In a specific operation of FIG. IV, the evaporatorsublimator 401 is supplied'with about 0.45 pounds of methane per second at a temperature of about 163 R. and discharges the vapors at about 135 R. at a pressure of 0.1354 psia. The vapors are passed to the absorber 402 and are mixed with about 1.1 pounds per second of propane having a'temperature of about 154.5 R. The pressure in the absorber 402 is about 0.0967 psia. The solution of methane in propane is discharged from the absorber at the rate of about 1.6 pounds per second and at a temperature of about 153 R. The solution passes to a heat exchanger corresponding to the heat exchanger 6 of FIG. I. In FIG. IV this heat exchanger has two sections 406 and 406'. The solution enters the section 406' and is heated by indirect heat exchanges with two separate sources of heat. One source of heat is the stream of propane returning from the regenerator 403 to the absorber. This stream is supplied at the rate of about 1.14 pounds per second at a temperature of about 159 R. The other source of heat is the condensed methane'from condenser 412 which has a temperature of about 229 R. and is passed through the heat exchanger at the rate of 0.45 pounds per second. Simultaneously, a minor stream of the condensed methane from condenser 412 is introduced into the solution of methane and propane in the heat exchanger section 406' by turbine 425. This stream is supplied at the rate of 0.19 pounds per second. The solution is discharged from the heat exchanger 406 at the rate of 1.79 poundsper second at a temperature of 155 R. The solution is then heated in heat exchanger section 406 to about 374 R, by the stream of propane returning to the absorber. The solution is pressurized by the 7 pumps 404 and 404' to a pressure of about 600 psia and is introduced into column 408 of the regenerator or separator 403. The regenerator 403 is heated by the coil 409 which received a heating medium at 658 R. The separated propane leaves the regenerator at a weight of 1.144 pounds per second at a temperature of 653 R. Before entering the heat exchanger 406, the stream of propane is cooled by passing through heat exchangers 427 and 428. The stream of propane is cooled by fluid passing through coils 421 and 422 to a temperature of about 449 R. The methane leaves the top of the column 408 at the rate of about 5.47 pounds per second and is transferred to heat exchanger 419 where the methane is cooled by fluid in the coil 420. The methane leaving the column 408 is at about 340 R. and is cooled to 336 R. in the heat exchanger 419. A major amount of the methane amounting to about 4.82 pounds per second is returned to the column 408 where it serves as reflux. The minor portion of the methane amounting to about 0.64 pounds persecond is transferred to the condenser 412. In condenser 412, the methane is cooled and liquified to a temperature about 229 R. and the stream is passed to the heat exchanger 406'. The major portion of the condensate amounting to 0.45 pounds per second passes through the coil 426 and is passed through the pressure reducing means 413 into the absorber 401. A minor portion of the con single operation, it should be noted that this operation requires only the addition of mechanical energy to operate the pumps 404 and 404. In this example, the heat supplied was at 658 R. or 199 F. which would be normally considered as waste heat. In this example, the heat supplied is such that Q= about 229 in the regenerator and the heat supplied to the evaporator is such that Q=100. Also in the example, the heat is removed in the exchangers 427 and 428 amounts to such that Q=164 and the amount removed by exchanger 419 amounts to such that Q=abm t 50 and the heat removed in the condenser is such that Q=124. From-these values, it will be appreciated that in the cycle a cooling effect of about one half of the heat supplied is obtained at a temperature of R. or 324 F. with the use of waste heat and minor amount of mechanical energy.
The quantities of refrigerant, absorbent and temperatures may be varied to suit specific problems without departing from the invention.
FIG. V illustrated one manner in which it contemplated to arrange two absorption refrigeratingcycles of this invention, in a cascade manner so as to utilize maximum percentage of the energy supplied to the system.
The Figure also illustrates how energy can be recovered in a cascade system. In each of the cycles shown in this Figure, the vapors of refrigerant are passed from coils in condensers 512 and 512' and then lead into the columns 508and 508'. The vapors from the columns 508 and 508 are passed through their respective heat exchangers 520 and 520. The vaporsare heated in these exchangers by heating fluid supplied to coils 524 and 524'. While the connection is not shown on the drawing for passing the returning absorbent from the regenerators 503 and 503to the heat exchangers 520 and 520', it is to be understood that a portion, at least of the heat supplied to the vapors, maybe derived from these sources as shown in FIG. Ill. The separate streams of .vapors heated in exchangers 520 and 520' are expanded by passing them through the corresponding turbines 523 and 523. The vapors from the turbines are then fed to the condensers 512 and 512' respectively and the energy in the liquid refrigerant recovered in the pressure reducing means 513 and 513' and the liquids passed to the evaporator-sublimators 501 and 501'.
In FIG. V the two cycles are shown as being in heat exchange relation by having a'heat transfer means 530 removing heat from condenser 512 and supplying the same heat to the regenerator 503'. Another heat transfer means 531 is shown for removing heat from the condenser 512 and absorber 502- and supplying this heat to the evaporator 501.
The turbines 507 and 507' perform the same functions as the corresponding parts in FIG. I, as do the heat exchangers 505, 509, 510 and 510'.
While the cascade arrangement is illustrated with only two cycles, three, four or more cycles can be constructed and connected in the manner shown. The'first cycle of a series could employ ethane as the refrigerant, the second could use methane, and subsequent cycles could employ nitrogen, neon, hydrogen and helium as refrigerants. The number of cycles and the refrigerant will be selected according to the needs of the system.
As shown by the several Figures of the drawing, the available heat in one portion of the system can be transferred to another location in the same cycle where the difference in temperature is sufficient to effect a worthwhile heat exchange. The area of the heat exchange surfaces will be selected to give the desired transfer of heat. The individual features may be combined when ever a significant saving of heat or energy will be effected.
' FIG. VI illustrates a generic arrangement for the liquification of a gas such as air, using the heat sink of an individual cycle or a plurality of cycles to remove the heat from the air. In this Figure, the details of the refrigeration cycles have been omitted and are indicated merely by the cooling coils in the heat exchangers 642 and 644.
Atmospheric air enters through a conduit 640 and is passed through the turbine 64] into a region of lower pressure and is passed through the heat exhangers 642 and 644 of the absorption refrigeration cycle. The cooling of the air is provided by substantially isentropic expansion in the turbine and by heat exchange with the heat sinks of the refrigeration evaporators in'the heat exchangers 642 and 644, where the air is condensed to liquid. The system'may be provided with known means to remove water vapor and carbon dioxide, to avoid fouling of the heat exchanger surfaces.
The liquid air is discharged from the heat exchanger 644 into conduit 645 and may be drawn off as a product by conduit 646. Alternatively, the liquid air may be I fed to separator 647,'which may be of known construction, e.g., a rectification column which will separate the liquid air into its components. Frequently, only nitrogen and oxygen will be separated, but the invention contemplates the recovery of the minor constituent gases of the atmosphere, e.g., argon, neon, helium, krypton, hydrogen xenon, ozone and radon, if desirable. The carbon dioxide in the air may also be recovered in the process.
The oxygen and nitrogen may be drawn off at 648 and 649, if desired, to use the separated element as such and may besupplied to other processes. The liquid air from conduit 645 may be passed to pump 661 where the fluid is pressurized. and then passed to coil 651. Similarly, the oxygen passes to pump 662 and coil 652, and the nitrogen to pump 663 and coil 653 of heat exchanger 650. The respective streams can then be passed, if desired, to turbines 657, 658 or 659 respectively. The product may be recovered by vessel 660. In
the event that oxygen is being passed through the 'tur-' bine 658, it may be desirable to mix the oxygen with a fuel which is introduced through conduit 656 and to ignite the mixture before-the combustion gas is passed through the turbine 658.
This Figure illustrates the many ways in which the ab-' sorption refrigeration system can be used commercially to recover energy and to supply liquid, air, oxygen, nitrogen, or the rare gases to industrial processes. Since '10 the process of refrigeration as described in this specification does not require the consumption of large amounts of energy, it provides these materials in an economical manner.
In FIG. VI, the heat exchanger 650 may also serve to transfer heat between two or more of the streams. As for instance the coil 65] which receives liquid air may serve to further cool other streams, or may be further cooled by the other streams. The coil 654 is indicated as a separate heat exchange means for an independent heat transfer medium to supply heat to or to remove heat from the exchanger 650, and may serve to transfer heat between the liquid air, the nitrogen or oxygen and the absorption refrigeration cycle. There may be a plurality of these means as desired. The vessel 660 into which the gases are individually collected may serve as a heat sink for the absorption refrigeration system or as an independent cooling means. 5
FIG. VII illustrates the basic system for recovering energy using a low temperature in the cycle with air as the energy transfer medium with liquifaction of the air. In this cycle the lowest temperature will be substantially the temperature of liquidair, and the highest temperature normally contemplated is that available from waste heat. While it is preferred to use waste heat as the source of the highest temperature in the cycle, it is,
clear that if 'the conditions are feasible the air can be tures in the cycle. A cascade refrigeration system as-illustrated in FIG. V is indicated by the block 770 in the drawing. This system is provided with heat transfer. means 771 to remove heat from the energy producing system. While only a single means 771 is indicated in the drawing it is to be understood that this means may be composed of a plurality of separate connections for transferring heat at different temperatures between the systems. I
The heat exchanger, which is shown diagrammatically, is supplied with a gas, usually air, which is condensed by the cooling effect of the transfer means to a liquid. While air is usually the gas employed, nitrogen or other gases can be used to avoidthe risk of combustion and oxidation. The liquid air from the heat exchanger 772 is passed to the pump 773 which increases the pressure on the liquid. The change in pressure is usual quite significant. The liquid at the higher pressure is circulated through the heat exchangers 774 and 775 and converted to gas at high pressure and, temperature and then is expanded through the turbine 776. The air leaving the turbine is cooled in heat exchanger 774 by heat exchange with the liquid air from the pump 773.-
The cooled air is then fed to the condenser or heat exchanger 772 completing the, cycle.
This Figure showsa simplified energy recovery sys- A est temperature in the proposed system is near absolute zero the efficiency of the system is high. The maximum Ill efficienty of a steam system is low since the temperature of condensation is high. As pointed out above, while the invention contemplates the use of waste heat, the air may be heated in heater 775 by heat from any source.
FIG. VIII illustrates a more developed system for recovering energy. This Figure employs the basic energy system set forth in FIG. VII. In this Figure, the absorption refrigeration system is indicated by the block 870. This absorption refrigeration system can be like the one shown in FIG. V but the details of the system have been omitted for the purpose of clarity. The refrigeration system is shown as removing heat from the energy recovery system by the heat transfer means 871 associated with the condenser or heat exchanger 872. The liquid gas which will be, hence forth referred for convenience as liquid air, is passed from the condenser 872 to the first pump 873 which increases the pressure of liquid air to about 50 psia. The pressurized liquid air is passed through the heat exchangers 874 and 874' and is heated by the air leaving the turbines. The liquid air is then pressurized by the pump 873 to a very high pressure such as 3500 psia., and is fed to the heat exchanger 874"; In this heater, the liquid air is vaporized and converted into gas at high pressure and much higher temperature. The hot gas is further heated in heat exchanger 875 and introduced into the turbine 876. The air as discharged from turbine 876 is reheated to about the original high temperature by the reheater 875' and is expanded through a second turbine 876'. The gas at lower pressure and temperature is reheated to about the original high temperature in reheater 875" and is expanded'through the third turbine 876". The air is then passed through the heat exchanger 874" and to the condenser 872 after passing through the cooler 890 and the heat exchangers 874 and 874.
As an example, this system can be arranged to circulate air at the rate of one pound per second through the cycle. If the pressure in the condenser is maintained at atmospheric pressure, the temperature in the condenser will be about l42 R. The liquid air is pressurized to about 50 psia. and passed through heat exchangers 874' and 874 and the temperature raised to about 165 R. The pump 873 raises the pressure to about 3,500 psia. and the temperature is raised to about 202 R. The liquid air is passed through the heaters 874 and 875 and is converted to gas at 700 R. (240 F.). The hot air is cooled in passing through the turbine 876 to 437 R. and the pressure is reduced to about 565 psia. In the heater 875', the air is returned to the temperature of 700 R. In turbine 87 6', the temperature is dropped to 473 R. and the pressure to about 91 psia. In the heater 875', the air is reheated to about 700 R. The expansion in turbine 876" drops the temperature of the air to 473 R. and the pressure to condition of the air discharged from the first turbine 876; Q, the condition of the air leaving the reheater 875 and entering the second turbine 876'; .10, the condition of the gas as discharged from the second turbine; 11, the condition-of the air leaving the second reheater 8'75" and entering the third turbine 876"; 12, the condition of the air as discharged from the third turbine; l3, l4, l5 and 16, the condition of the air as it is cooled and returned to the condenser at point 1.
The liquid air flowing from the condenser 872 is pressurized by the pump 873 (point 2 on the chart) and is returned in indirect heat exchange in heater 874 to absorb part of the latent heat of the condensing air. This transfer of energy is possible with air, as air is essentially a binary mixture of oxygen and nitrogen, and the dew point temperature is approximately 55 F. higher than its bubble point. The heat exchanger 874 warms the liquid air to slightly below its saturation point (point 4 on the chart). The liquid is pressurized by pump 873' to the pressure at turbine inlet (point 8on the chart). The liquidat high pressure is vaporized in the heat exchanger 875. In this heat exchanger, the highest temperature in the cycle is reached. The temperature shown can readily be reached by employing low quality thermal energy, such as waste heat. Nothing in this disclosure should be construed as preventing the use of higher temperatures which can be obtained from other heat sources.
The system shown, when supplied with air at the rate of one pound per second, would produce about two hundred horsepower in excessof that required to operate the pumps 873 and 873, subject to the limitation of the efficiencies of the turbines and losses in the systern.
FIG. IX illustrates another embodiment of the'invention for the recovery of energy, preferably using the absorption refrigeration system as a means for establishing the necessary temperature differential. In this Figatmospheric. The air is cooled in the heat exchangers tion of the liquid air leaving the. pump 873; 3, 4 and 5,
the condition of the liquid air leaving the heat exchanger 874, 874' and 875'; 6, the condition of the air leaving the pump 873'; 7, the condition of the air leaving the heater 875 and entering the turbine 876; 8, the
This Figure shows an arrangement generally corresponding to the system .of FIG. VIII, but in which the construction has been simplified. This Figure shows an arrangement which will allow a substantial recovery of power with a lower plant investment. The actual selection of the number of turbines and the number of reheaters will depend upon an economic balance between the cost of equipment and the value of the power drived.
FIG. X illustrates the recovery of pure water by the use of a low grade heat source. In theproduction of water from saline water or impure water, one of the major problems has been the cost of the power required to vaporize the water. Another problem has beenthe scaling of the water in the heating vessels. The utilization of the absorption refrigeration systems of this invention will overcome some of these previous difficulities.
In FIG. X the evaporator of the absorption refrigeration system is indicated as 1001, the refrigerant absorber as 1002, the pump for the solution of refrigerant and absorbent as 1004, the regenerator as 1003 and the column as 1008. The vapors of the, refrigerant are passed to the heater 1019 and are heated by indirect heat exchange with theabsorbent from the regenerator 1003. The heated vapors are then expanded through the turbine. 1020, to recover energy and to cool the vapors. The vapors are condensed in condenser 1012 and the liquid refrigerant is passed through the pressure reduction means 1013 to the evaporator 1001. The refrigeration system thus far disclosed is similar to that shown in FIG. IV.
The condenser 1012 includes a heat exchanger element-102l through which is passed the water to be distilled. The refrigerant and the pressure of condensation are selected so that the heat of the condensing vapors heats the water to be distilled. The warmed water is then passed to the heat exchange element 1006' in the heat exchanger 1006, and the water is further heated by the absorbent returning to the absorber 1002 from the regenerator 1003.
The hot water isthen fed into the distillation system. The distillation system comprises a series of flash chambers which utilize the latent heat in the water to vaporize a portion of the water. The hot water is introduced in the first flash chamber 1080, and a portion of the water flashed into steam. The steam is fed through the heat exchange means 1082 in the second flash,
chamber'1081 and is condensed. The water from the first flash chamber is fed to the second chamber 1081 which is ata lower pressure. A second quantity of water flashes into steam. While only two flash chambers are shown, it is to be understood ,that the number of flash chambers may be selected according to the design criteria of such distillation systems. i
The vapors from the final flash chamber and the condensate from the heat exchanger 1082 are fed into the condensing chamber 1083. This chamber is cooled by heat exchange element 1084 through which is circulateda heat exchanger medium which also is passed through the element 1014 of the evaporator 1001. The non-condensible gases in the saline water are removed from the distillation system by the ejector 1086. The evaporator 1001 which is heated by the condensing water vapor in the condenser 1083, will maintain a minimum pressure and temperature in the water vapor condenser. The unevaporated water or waste brine from the final distillation stage is discharged through the heat exchangemeans 1087 in the refrigerant condenser 1012 or through the heat exchange means 1088 in the refrigerant absorber 1002, to remove the heat of these elements. In a like manner, the distilled water is passed through the heat exchanger means 1089 in the refrigerant condenser 1012 or through the heat ex-- change means 1091 in the absorber 1002 or through both.
FIG. X demonstrates the application of absorption refrigeration system ofthis invention using a low temperature heat source to produce energy and to performuseful chemical engineering unit process operations. While this example shows the application of the process ofthis invention to the distillation of water, it is apparent that other liquids could be distilled in a similar manner. Furthermore, the temperature differential available from the absorption refrigeration cycles of this invention can be used in other unit processes requiring temperature changes. For example, water could be purified by freezing rather than by distillation. The invention could also be used to dehydrate materials as by freeze drying since the invention can produce both low temperature and low pressure.
FIG. XI shows the construction of a preferred form of the evaporator-sublimator of this invention. The figure is a cross section through the vessel constituting the evaporator-sublimator. Thevessel is normally provided with insulation about the walls. The interior of the vessel is divided into a liquid receiving section 1101 and a vapor section 1103 with a porous plate 1 102 separating the section from each other. The liquid to be vaporized is introduced into the section 1101 by the pipe 1104. The vapor is removed'from section 1103 by the pipe 1105. This pipe is designed to maintain the pressure in the section 1103 at a desired level. The pipe 1105 may include a fan, if necessary, to maintain the desired pressure.
The porous plate 1102 which serves as a partition, is formed of an open cell 'material such as porous brick or stone or metal which will permit the slow passage of the liquid through the partition. The partition includes a heat exchange means 1114 which will supply the heat necessary to vaporize the liquid. This heat exchange means serves as the heat sink in the refrigeration cycle.
e which is below the triple point of the refrigerant. Under these conditions, the refrigerant, as it passes through the partition 1 102, will freeze in the passages and block further flow of liquid. The heat exchange means 111'4 will supply heat to sublimate the refrigerant. As the refrigerant is evaporated, more liquid refrigerants will pass into the plate and be frozen. Thus, the passage for the liquid is automatically limited to the rate at which the frozen material is sublimed by the heat.
When the pressure in the chamber is above the triple point of refrigerant, the liquid will ooze through the plate and be heated by the heat exchange means and will evaporate into the chamber 1102. This will occur before the system has reached the triple point pressure at the time the system is being started up or the system can be operated under these conditions as desired.
FIG. XII is another embodiment of the evaporatorsublimator. In this Figure, the liquid chamber is desig nated as 1201, the vapor chamber as 1203 and the porous plate as 1202. The liquid is supplied by pipe 1204 and the vapor removed by pipe 1205. This embodiment differs from that shown in FIG. XI by having thefeed pipe 1204 pass through the vapor section 1203.. This pipe includes the heat exchange means 1207 -in the vapor section. This permits the liquid refrigerant to be further cooled before entering the chamber 1201'. This construction assures a rapid stabilization of conditions to enable the operation of the evaporator-sublimator as a sublimator. The heat sink is designated by the heat exchange means 1214. I
FIG. XIII shows a vapor separator particularly adapted to be used in the flash distillation-chambers of the system shown in FIG. Xl While particularly adapted for this type of system, the separator can be used in any distillation system benefitted by little or no entrainment of the distilland in the vapor. In this Figure, 1301 indicates the vessel for receiving the liquid to be distilled through the pipe 1302 and discharging the vaporthrough the pipe 1303. In the vessel above the level of the boiling liquid is a baffle means 1304. This baffle means includes a shaft 1305 which is mounted for rotation about an axis. A series of turbine blades 1307 are secured in an inclined position to the shaft so that the passage of vapor towards the outlet pipe 1303 cause the shaft to rotate. A perforate plate 1306 secured to the shaft above the turbine blades rotates with the shaft. The plate, preferably in the form of a fine mesh screen, engages any droplets of liquid and centrifugally throws them outwardly away from the outlet. While it is preferred to have the vapors rotate the screen, it would be possible to use other means for the purpose.
' FIGS. XV and XVI illustrate a more specific embodiment of the cycles shown in FIG. VI. In these Figures, the energy recovery system is used to provide motive power for a vehicle. The vehiclemay be any vehicle requiring energy forpropulsion, such as aircraft, boats, air-cushioned vehicles as Hovercraft and trains, railroad cars, road vehicles or tube cars. The power derived can beused directly as in the thrust of a jet or indirectly by the use of a driven turbine.
In FIG. XV, the heat sink of an absorption refrigeration system is indicated by the block 1570. The power generating system receives air from the atmosphere at 1560-The entrance may be in the form of a scoop, taking advantage of the vehicles forward motion to increase the flow of air. The entering air is passed to the precooler 1571 and is conveyed from there to the turbocompressor 1572. The compressed air passes through the heat exchange means 1573 in the pre- "cooler. The compressed air is fed to theturbine 1574 and there expanded. The cooled air is then passed into the condenser 1577, in which it is further cooled by supplying heat to the refrigeration cycle, and is condensed to a liquid. The liquid air is pressurized by the pump 1575 and passed to the heat exchanger 1576 in the refrigeration cycle. This exchanger heats the air to transfer heat from the refrigeration cycle to the pre-- cooler, to .the condenser, andtothe heater. The precooler will use well-known techniques to free the air from ice, carbon dioxide and the like and to remove the ice from the precooler.
The thrust means 1578 may be a jet engine or a rocket nozzle or a turbojet engine. While it is desirable, in many instances, to use fuel in the engine, wherever the added heat of combustion or the polluting effect of combustion is to be avoided, the engine may be powered solely by the expanding gas.
FIG. XVI illustrates another embodiment of the invention as used for the propulsion of a vehicle. In this Figure, the air enters the system at 1660 and is passed to the precooler 1671. The dried cooled air is fed to the compressor 1672. The compresser gas then is passed to the heat exchanger 1673 in the precooler and then fed to the turbine 1674 and is there expanded. The air is condensed in condenser 1677. The liquid air is passed through the heat exchange means 1683 in the pre- FIG. XVII shows an embodiment of theinvention as applied to the use of gases such as nitrogen, hydrogen, neon and helium as refrigerants.
FIG. XVII illustrates one absorption refrigeration cycle of a cascade system. In this Figure, the absorber 1702 feeds the solution of a gas such as hydrogen in a liquid hydrocarbon to the pump 1704 and hence to the heat exchanger 1706 and to the column 1.708 of the regenerator or separator 1703. The heat necessary to separate the gas from the absorbent is preferably supplied bythe condenser of another cycle in the cascade arrangement by means 1709. The gas is then supplied to 'a heat exchanger 1712. This exchanger is arranged to remove heat from the gas and supply this heat to an evaporator of another cycle in the cascade system. This heat exchanger also includes another heat exchange element 1721. The cooled gas from theheat exchanger 1712 is passed through the expansion means 1713 into the chamber 1722. This chamber is at lower pressure than 1712 and a portion of the gas is liquified and is passed ,into the evaporator-sublimator 1701. The v'apors from the evaporator-sublimator 1701 and the vapassed through the heat exchanger element 17 21 in the chamber 1712 and then passed to the absorber 1702.
The vapors separated from the liquid andthe vapors from the evaporator-sublimator thus serve to cool the gas in the chamber 1712.
When hydrogen is the refrigerant, the heat exchanger 1712 may be cooled by the heat sink of an evaporatorsublimator of another cycle of the cascade to 94 R. The hydrogen is further cooled-by the heat exchange element 1721 by the hydrogen from the evaporator and the chamber 1722. The hydrogen is cooled to the liquefaction by passage through the expansion means 1713.
'The liquid hydrogen from chamber. 1722 may be passed to the evaporator 1701 in which it may serve as the heat sink in connection with a cooler cycle for liquidrogen, and will include the expansion of neon in the means 1713. It is desirable to include acycle in the cascade system, and then the neon heat sink will be used tions of the invention to adapt it to various usages and conditions.
What is claimed is:
l. A refrigeration process comprising the steps of:
absorbing a refrigerant vapor in a liquid absorbent;
increasing the pressure on resultant mixture of said refrigerant and said absorbent;
distilling and rectifying the mixture into substantially pure refrigerant vapor and pure absorbent;
reducing the pressure on resultant pure liquid absorbent and returning the latter to the absorbing step;
cooling and condensing the refrigerant vapor to the liquid state;
reducing the pressure upon the liquid refrigerant to below the triple point of the refrigerant to. produce solid refrigerant;
sublimating the solid refrigerant to the vapor state;
and
passing resultant refrigerant vapor to the absorbing step at a rate that maintains the pressure below the triple point.
2. A process according to claim 1 wherein prior to the sublimating step the liquid refrigerant is passed through a porous plate and solid refrigerant is formed in said plate.
3. A process according to claim 2 wherein the porous plate is heated to sublimate the refrigerant.
4. A process according to claim 1 wherein the passage of the refrigerant from the sublimation step to the absorbing step is induced by mechanical means.
5. A processaccording to claim 1 in which the pressure on the liquid absorbent is reducedby passing said liquid absorbent through a turbine, thereby recovering energy therefrom.
6. A process according to claim 1 in which the refrigerant is selected from the group consisting of nitrogen, hydrogen, neon, helium and hydrocarbon having a saturationpressure between that of butane and methane;
and the absorbent is a liquid having a freezing point below the temperature of the process and selected from the group consisting of a hydrocarbon liquid and an inorganic liquid.
7. A process according to claim 1 wherein the refrigerant is methane and the absorbent is selected from ethane and propane. v
8. A process according to claim ing and condensing of the refrigerant is conducted in heat exchange with a separate absorbent refrigeration cycle.
9. A process according to claim 1 wherein the heat for distilling and rectifying the mixture is supplied by heat exchange with a separate absorbent refrigeration cycle.
10. A process for the recovery of energy and refriger ation comprising the steps of: r absorbing a refrigerant vapor in a liquid absorbent; increasing the pressure on the resultant mixture of refrigerant and absorbent; distilling and rectifying the mixture into substantially pure refrigerant vapor and pure absorbent;
heating the refrigerant vapor from the distillation step by indirect heat exchange with absorbent'from the distillation step, to simultaneously increase the temperature of the vapor'refrigerant and reduce the temperature and pressure of the liquid absorbent;
recovering energy from the refrigerant vapor by reducing its temperature and pressure;
condensing the vaporous refrigerant to the liquid state; recovering the energy of the liquid refrigerant by reducing its pressure and temperature;
evaporating the 'liquid refrigerant under reduced pressure; and
returning the absorbent and the refrigerant to the absorbing step;
1 wherein the cool- I
Claims (10)
1. A refrigeration process comprising the steps of: absorbing a refrigerant vapor in a liquid absorbent; increasing the pressure on resultant mixture of said refrigerant and said absorbent; distilling and rectifying the mixture into substantially pure refrigerant vapor and pure absorbent; reducing the pressure on resultant pure liquid absorbent and returning the latter to the absorbing step; cooling and condensing the refrigerant vapor to the liquid state; reducing the pressure upon the liquid refrigerant to below the triple point of the refrigerant to produce solid refrigerant; sublimating the solid refrigerant to the vapor state; and passing resultant refrigerant vapor to the absorbing step at a rate that maintains the pressure below the triple point.
2. A process according to claim 1 wherein prior to the sublimating step the liquid refrigerant is passed through a porous plate and solid refrigerant is formed in said plate.
3. A process according to claim 2 wherein the porous plate is heated to sublimate the refrigerant.
4. A process according to claim 1 wherein the passage of the refrigerant from the sublimation step to the absorbing step is induced by mechanical means.
5. A process according to claim 1 in which the pressure on the liquid absorbent is reduced by passing said liquid absorbent through a turbine, thereby recovering energy therefrom.
6. A process according to claim 1 in which the refrigerant is selected from the group consisting of nitrogen, hydrogen, neon, helium and hydrocarbon having a saturation pressure between that of butane and methane; and the absorbent is a liquid having a freezing point below the temperature of the process and selected from the group consisting of a hydrocarbon liquid and an inorganic liquid.
7. A process according to claim 1 wherein the refrigerant is methane and the absorbent is selected from ethane and propane.
8. A process according to claim 1 wherein the cooling and condensing of the refrigerant is conducted in heat exchange with a separate absorbent refrigeration cycle.
9. A process according to claim 1 wherein the heat for distilling and rectifying the mixture is supplied by heat exchange with a separate absorbent refrigeration cycle.
10. A process for the recovery of energy and refrigeration comprising the steps of: absorbing a refrigerant vapor in a liquid absorbent; increasing the pressure on the resultant mixture of refrigerant and absorbent; distilling and rectifying the mixture into substantially pure refrigerant vapor and pure absorbent; heating the refrigerant vapor from the distillation step by indirect heat exchange with absorbent from the distillation step, to simultaneously increase the temperature of the vapoR refrigerant and reduce the temperature and pressure of the liquid absorbent; recovering energy from the refrigerant vapor by reducing its temperature and pressure; condensing the vaporous refrigerant to the liquid state; recovering the energy of the liquid refrigerant by reducing its pressure and temperature; evaporating the liquid refrigerant under reduced pressure; and returning the absorbent and the refrigerant to the absorbing step.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US00152332A US3854301A (en) | 1971-06-11 | 1971-06-11 | Cryogenic absorption cycles |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US00152332A US3854301A (en) | 1971-06-11 | 1971-06-11 | Cryogenic absorption cycles |
Publications (1)
Publication Number | Publication Date |
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US3854301A true US3854301A (en) | 1974-12-17 |
Family
ID=22542472
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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US00152332A Expired - Lifetime US3854301A (en) | 1971-06-11 | 1971-06-11 | Cryogenic absorption cycles |
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US (1) | US3854301A (en) |
Cited By (33)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4083194A (en) * | 1976-12-02 | 1978-04-11 | Fluor Engineers And Constructors, Inc. | Process for recovery of liquid hydrocarbons |
US4111002A (en) * | 1976-02-25 | 1978-09-05 | U.S. Philips Corporation | Cyclic desorption refrigerator and heat pump, respectively |
FR2412798A1 (en) * | 1977-08-10 | 1979-07-20 | Vaillant Sa | SORPTION HEAT PUMP |
US4321799A (en) * | 1980-03-28 | 1982-03-30 | Georgia Tech Research Institute | Method for utilizing gas-solid dispersions in thermodynamic cycles for power generation and refrigeration |
EP0061721A1 (en) * | 1981-03-24 | 1982-10-06 | Georg Prof. Dr. Alefeld | Multi-stage apparatus with circulation circuits for working fluids and for absorbing media, and method to operate such an apparatus |
FR2519416A1 (en) * | 1982-01-07 | 1983-07-08 | Inst Francais Du Petrole | PROCESS FOR PRODUCING COLD AND / OR HEAT USING THE CARBON DIOXIDE AND A CONDENSABLE FLUID |
EP0086768A1 (en) * | 1982-02-04 | 1983-08-24 | Sanyo Electric Co., Ltd | Absorption heat pump system |
EP0156050A1 (en) * | 1982-12-06 | 1985-10-02 | Gas Research Institute | Absorption refrigeration and heat pump system |
FR2563615A1 (en) * | 1984-04-25 | 1985-10-31 | Inst Francais Du Petrole | NOVEL PROCESS FOR THE PRODUCTION OF COLD AND / OR ABSORPTION HEAT USING A MIXTURE OF SEVERAL COMPONENTS AS A WORKING FLUID |
FR2573184A1 (en) * | 1984-11-13 | 1986-05-16 | Carrier Corp | REFRIGERATION MACHINE / HEAT PUMP WITH ABSORPTION, WITH TWO COUPLED BUCKLES |
US4678587A (en) * | 1984-12-10 | 1987-07-07 | Voinche Jack L | Water distillation method |
US4697425A (en) * | 1986-04-24 | 1987-10-06 | The United States Of America As Represented By The Administrator Of The National Aeronautics And Space Administration | Oxygen chemisorption cryogenic refrigerator |
US4718242A (en) * | 1986-01-09 | 1988-01-12 | Shinryo Corporation | Chemical heat pump utilizing clathrate formation reaction |
US4875346A (en) * | 1989-01-31 | 1989-10-24 | The United States Of America As Represented By The Administrator Of The National Aeronautics And Space Administration | Two-statge sorption type cryogenic refrigerator including heat regeneration system |
EP0887600A2 (en) * | 1997-06-24 | 1998-12-30 | L.D.H. Srl. | Perfected absorption cooling plant and relative working method |
US20040231346A1 (en) * | 2001-06-06 | 2004-11-25 | Smith Douglas M. | Sorption cooling devices |
US20090020406A1 (en) * | 2007-07-16 | 2009-01-22 | Arrowhead Center, Inc. | Desalination Using Low-Grade Thermal Energy |
US20100154419A1 (en) * | 2008-12-19 | 2010-06-24 | E. I. Du Pont De Nemours And Company | Absorption power cycle system |
WO2011079271A2 (en) * | 2009-12-24 | 2011-06-30 | General Compression Inc. | Methods and devices for optimizing heat transfer within a compression and/or expansion device |
US8272212B2 (en) | 2011-11-11 | 2012-09-25 | General Compression, Inc. | Systems and methods for optimizing thermal efficiencey of a compressed air energy storage system |
US8286659B2 (en) | 2009-05-22 | 2012-10-16 | General Compression, Inc. | Compressor and/or expander device |
US20130091893A1 (en) * | 2011-10-12 | 2013-04-18 | Chang-Hsien TAI | Gas liquefaction apparatus |
US20130111935A1 (en) * | 2010-07-23 | 2013-05-09 | Carrier Corporation | High Efficiency Ejector Cycle |
US8454321B2 (en) | 2009-05-22 | 2013-06-04 | General Compression, Inc. | Methods and devices for optimizing heat transfer within a compression and/or expansion device |
US8522538B2 (en) | 2011-11-11 | 2013-09-03 | General Compression, Inc. | Systems and methods for compressing and/or expanding a gas utilizing a bi-directional piston and hydraulic actuator |
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US8572959B2 (en) | 2011-01-13 | 2013-11-05 | General Compression, Inc. | Systems, methods and devices for the management of heat removal within a compression and/or expansion device or system |
US8997475B2 (en) | 2011-01-10 | 2015-04-07 | General Compression, Inc. | Compressor and expander device with pressure vessel divider baffle and piston |
US9109512B2 (en) | 2011-01-14 | 2015-08-18 | General Compression, Inc. | Compensated compressed gas storage systems |
US10330331B2 (en) * | 2015-11-24 | 2019-06-25 | Southeast University | Independent temperature and humidity processing air conditioning system driven by low-level thermal energy |
US11397030B2 (en) * | 2020-07-10 | 2022-07-26 | Energy Recovery, Inc. | Low energy consumption refrigeration system with a rotary pressure exchanger replacing the bulk flow compressor and the high pressure expansion valve |
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Citations (9)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US1982672A (en) * | 1930-04-24 | 1934-12-04 | Drucktransformatoren Koenemann | Process for the simultaneous generation of coldness and steam under pressure |
US2667764A (en) * | 1950-01-18 | 1954-02-02 | Hudson Engineering Corp | Refrigeration method, system, and apparatus |
US2751748A (en) * | 1951-09-03 | 1956-06-26 | Bachl Herbert | Thermodynamic plural-substance processes and plants for converting heat into mechanical energy |
US3041853A (en) * | 1955-11-25 | 1962-07-03 | Harwich Stanley | Refrigerating process and apparatus for the same |
US3145304A (en) * | 1962-05-21 | 1964-08-18 | Singer Co | Photoelectric motor-speed foot controller |
US3170303A (en) * | 1963-08-20 | 1965-02-23 | United Aircraft Corp | Sublimator |
US3197973A (en) * | 1964-10-14 | 1965-08-03 | United Aircraft Corp | Refrigeration system with sublimator |
US3483710A (en) * | 1968-06-13 | 1969-12-16 | Crane Co | Cascade absorption refrigeration system |
US3505810A (en) * | 1966-12-02 | 1970-04-14 | Gohee Mamiya | System for generating power |
-
1971
- 1971-06-11 US US00152332A patent/US3854301A/en not_active Expired - Lifetime
Patent Citations (9)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US1982672A (en) * | 1930-04-24 | 1934-12-04 | Drucktransformatoren Koenemann | Process for the simultaneous generation of coldness and steam under pressure |
US2667764A (en) * | 1950-01-18 | 1954-02-02 | Hudson Engineering Corp | Refrigeration method, system, and apparatus |
US2751748A (en) * | 1951-09-03 | 1956-06-26 | Bachl Herbert | Thermodynamic plural-substance processes and plants for converting heat into mechanical energy |
US3041853A (en) * | 1955-11-25 | 1962-07-03 | Harwich Stanley | Refrigerating process and apparatus for the same |
US3145304A (en) * | 1962-05-21 | 1964-08-18 | Singer Co | Photoelectric motor-speed foot controller |
US3170303A (en) * | 1963-08-20 | 1965-02-23 | United Aircraft Corp | Sublimator |
US3197973A (en) * | 1964-10-14 | 1965-08-03 | United Aircraft Corp | Refrigeration system with sublimator |
US3505810A (en) * | 1966-12-02 | 1970-04-14 | Gohee Mamiya | System for generating power |
US3483710A (en) * | 1968-06-13 | 1969-12-16 | Crane Co | Cascade absorption refrigeration system |
Non-Patent Citations (1)
Title |
---|
Refrigeration and Air Conditioning, W. F. Stoecker, McGraw Hill, 1958, p. 37. * |
Cited By (56)
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US4111002A (en) * | 1976-02-25 | 1978-09-05 | U.S. Philips Corporation | Cyclic desorption refrigerator and heat pump, respectively |
US4083194A (en) * | 1976-12-02 | 1978-04-11 | Fluor Engineers And Constructors, Inc. | Process for recovery of liquid hydrocarbons |
FR2412798A1 (en) * | 1977-08-10 | 1979-07-20 | Vaillant Sa | SORPTION HEAT PUMP |
US4321799A (en) * | 1980-03-28 | 1982-03-30 | Georgia Tech Research Institute | Method for utilizing gas-solid dispersions in thermodynamic cycles for power generation and refrigeration |
EP0597822A2 (en) * | 1981-03-24 | 1994-05-18 | Alefeld, geb. Dengscherz, Helga Erika Marie | Multi-stage apparatus with circulation circuits for working fluids and for absorbing media, and method of operating such an apparatus |
EP0061721A1 (en) * | 1981-03-24 | 1982-10-06 | Georg Prof. Dr. Alefeld | Multi-stage apparatus with circulation circuits for working fluids and for absorbing media, and method to operate such an apparatus |
WO1982003448A1 (en) * | 1981-03-24 | 1982-10-14 | Georg Alefeld | Installation with a plurality of stages comprising circuits of fluids and absorption agents,and method for operating such installation |
EP0597822A3 (en) * | 1981-03-24 | 1995-02-08 | Alefeld Georg | Multi-stage apparatus with circulation circuits for working fluids and for absorbing media, and method of operating such an apparatus. |
EP0087540A2 (en) * | 1982-01-07 | 1983-09-07 | Institut Français du Pétrole | Method of producing cold and/or heat by the use of carbon dioxide and a condensable fluid |
EP0087540A3 (en) * | 1982-01-07 | 1983-11-16 | Institut Francais Du Petrole | Method of producing cold and/or heat by the use of carbon dioxide and a condensable fluid |
FR2519416A1 (en) * | 1982-01-07 | 1983-07-08 | Inst Francais Du Petrole | PROCESS FOR PRODUCING COLD AND / OR HEAT USING THE CARBON DIOXIDE AND A CONDENSABLE FLUID |
EP0086768A1 (en) * | 1982-02-04 | 1983-08-24 | Sanyo Electric Co., Ltd | Absorption heat pump system |
EP0156050A1 (en) * | 1982-12-06 | 1985-10-02 | Gas Research Institute | Absorption refrigeration and heat pump system |
FR2563615A1 (en) * | 1984-04-25 | 1985-10-31 | Inst Francais Du Petrole | NOVEL PROCESS FOR THE PRODUCTION OF COLD AND / OR ABSORPTION HEAT USING A MIXTURE OF SEVERAL COMPONENTS AS A WORKING FLUID |
EP0162746A1 (en) * | 1984-04-25 | 1985-11-27 | Institut Français du Pétrole | Absorption process for producing cold and/or heat using a mixture of several constituents as a working fluid |
FR2573184A1 (en) * | 1984-11-13 | 1986-05-16 | Carrier Corp | REFRIGERATION MACHINE / HEAT PUMP WITH ABSORPTION, WITH TWO COUPLED BUCKLES |
US4678587A (en) * | 1984-12-10 | 1987-07-07 | Voinche Jack L | Water distillation method |
US4718242A (en) * | 1986-01-09 | 1988-01-12 | Shinryo Corporation | Chemical heat pump utilizing clathrate formation reaction |
US4697425A (en) * | 1986-04-24 | 1987-10-06 | The United States Of America As Represented By The Administrator Of The National Aeronautics And Space Administration | Oxygen chemisorption cryogenic refrigerator |
US4875346A (en) * | 1989-01-31 | 1989-10-24 | The United States Of America As Represented By The Administrator Of The National Aeronautics And Space Administration | Two-statge sorption type cryogenic refrigerator including heat regeneration system |
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US20040231346A1 (en) * | 2001-06-06 | 2004-11-25 | Smith Douglas M. | Sorption cooling devices |
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