AIR SEPARATION REFRIGERATION SUPPLY METHOD

Abstract

A method of supplying refrigeration to air separation plants within an air separation plant facility in which a refrigerant stream is produced at cryogenic temperature within a centralized refrigeration system. Streams of the refrigerant at the cryogenic temperature are introduced into the air separation plants such that all or a part of the refrigeration requirements of the air separation plants are supplied by the streams of the refrigerant.

Claims

1. A method of supplying refrigeration to air separation plants located within an air separation plant facility, such method comprising: separating air within at least two air separation plants to produce products including a nitrogen-rich vapor stream, wherein the air to be separated in the first of the at least two air separation plants comprises a first compressed air stream that is introduced into a liquid expander and subsequently introduced into at least one of a higher pressure column and a lower pressure column of the first of the at least two air separation plants and a second compressed air stream that is expanded to produce an exhaust stream and the exhaust stream is introduced into the higher pressure column, thereby to impart part of the refrigeration requirements of the first of the at least two air separation plants; withdrawing the nitrogen-rich vapor stream from the first of the at least two air separation plants; liquefying the nitrogen-rich vapor stream within a refrigeration system to produce a nitrogen-rich liquid refrigerant at a cryogenic temperature as a nitrogen-rich liquid; and introducing one or more streams of the nitrogen-rich liquid refrigerant, while at the cryogenic temperature, directly from the refrigeration system into the other of the at least two air separation plants such that all or a part of the refrigeration requirements of the other of the at least two air separation plants are supplied by the one or more streams of the nitrogen-rich liquid refrigerant.

2. The method of claim 1, wherein the refrigeration system is operated on an intermittent basis such that liquid production of the air separation plants is increased during operation of the refrigeration system.

3. The method of claim 1, wherein the nitrogen-rich vapor stream is liquefied in the refrigeration system by compressing and cooling a portion of the nitrogen-rich vapor contained within the nitrogen-rich vapor stream and refrigeration for the cooling is generated at least in part by expanding another portion of the nitrogen-rich vapor within a turbo expander.

4. The method of claim 1, wherein: the nitrogen-rich vapor is produced as a column overhead of the lower pressure column of the first of the air separation plants; the nitrogen-rich vapor stream is fully warmed within a main heat exchanger of the first of the air separation plants; and at least one of the nitrogen-rich liquid refrigerant streams is introduced into the first of the air separation plants as reflux to the higher pressure column.

5. The method of claim 4, wherein: an oxygen-rich liquid stream is pumped to produce a pumped liquid oxygen stream; at least part of the pumped liquid oxygen stream is vaporized or pseudo vaporized within the main heat exchanger through indirect heat exchange with the first compressed air stream.

6. A method of supplying refrigeration to air separation plants located within an air separation plant facility, such method comprising: separating air within the air separation plants to produce products including a nitrogen-rich vapor stream, wherein the air to be separated in the first of the air separation plants comprises a first compressed air stream that is introduced into a liquid expander and introduced into at least one of a higher pressure column and a lower pressure column of the first of the air separation plants and a second compressed air stream that is expanded to produce an exhaust stream and the exhaust stream is introduced into the higher pressure column, thereby to impart part of the refrigeration requirements of the first of the air separation plants; withdrawing the nitrogen-rich vapor stream from at least one of the air separation plants; liquefying the nitrogen-rich vapor stream within a refrigeration system to produce a nitrogen-rich liquid refrigerant at a cryogenic temperature as a nitrogen-rich liquid; and introducing one or more streams of the nitrogen-rich liquid refrigerant, while at the cryogenic temperature, into the air separation plants such that all or a part of the refrigeration requirements of the air separation plants are supplied by the one or more streams of the nitrogen-rich liquid refrigerant to increase liquid production and at least one of the nitrogen-rich liquid refrigerant streams is introduced into the first of the air separation plants as reflux to the higher pressure column; wherein the nitrogen-rich vapor is produced as a column overhead of the lower pressure column of the first of the air separation plants and the nitrogen-rich vapor stream is fully warmed within a main heat exchanger of the first of the air separation plants; wherein an oxygen-rich liquid stream is pumped to produce a pumped liquid oxygen stream and at least part of the pumped liquid oxygen stream is vaporized or pseudo vaporized within the main heat exchanger through indirect heat exchange with a compressed air stream; and wherein the compressed air stream after the indirect heat exchange is introduced into a liquid expander and introduced into at least one of the higher pressure column and the lower pressure column, thereby to impart part of the refrigeration requirements of the at least first of the air separation plants.

Description

BRIEF DESCRIPTION OF THE DRAWING

[0015] While the specification concludes with claims distinctly pointing out the subject matter that Applicant regards as his invention, it is believed that the invention will be better understood when taken in connection with the accompanying drawings in which:

[0016] FIG. 1 is a schematic illustration of an air separation facility for carrying out a method in accordance with the present invention;

[0017] FIG. 2 is a schematic illustration of an air separation plant used within the facility of FIG. 1 and

[0018] FIG. 3 is a schematic illustration of a liquefier used in connection with the facility illustrated in FIG. 1.

DETAILED DESCRIPTION

[0019] With reference to FIG. 1, an air separation facility is illustrated having air separation plants 1 and 2 and a central refrigeration system 3. In the particular installation, a nitrogen-rich stream 4 is used as the working fluid and is liquefied within central refrigeration system 3 to produce a refrigerant stream 5 at a cryogenic temperature. Streams 6 and 7 of the refrigerant stream 5 are fed back to the air separation plants 1 and 2 while at the cryogenic temperature to supply all or part of their refrigeration requirements. In the specific embodiment discussed herein, the streams 6 and 7 are nitrogen-rich liquid streams produced by liquefaction of a nitrogen-rich vapor stream. As such, refrigeration system 3 is a liquefier in the following discussion. It is to be noted that the present invention is not limited to such embodiments and other types of refrigeration systems are possible including closed-loop refrigeration system having a refrigerant medium that is capable of being produced at cryogenic temperature.

[0020] With reference to FIG. 2, air separation plant 1 is illustrated. An air feed stream 10 is introduced into an air separation plant 1 to separate nitrogen from oxygen. Air feed stream 10 is compressed within a first compressor 12 to a pressure that can be between about 5 bara and about 15 bara. Compressor 12 may be an intercooled, integral gear compressor with condensate removal that is not shown.

[0021] After compression, the resultant compressed feed stream 14 is introduced into a prepurification unit 16. Prepurification unit 16 as well known in the art typically contains beds of alumina and/or molecular sieve operating in accordance with a temperature and/or pressure swing adsorption cycle in which moisture and other higher boiling impurities are adsorbed. As known in the art, such higher boiling impurities are typically, carbon dioxide, water vapor and hydrocarbons. While one bed is operating, another bed is regenerated. Other process could be used such as direct contact water cooling, refrigeration based chilling, direct contact with chilled water and phase separation.

[0022] The resultant compressed and purified feed stream 18 is then divided into a stream 20 and a stream 22. Typically, stream 20 is between about 25 percent and about 35 percent of the compressed and purified feed stream 18 and as illustrated, the remainder is stream 22.

[0023] Stream 20 is then further compressed within a compressor 23 which again may comprise intercooled, integral gear compressor. The second compressor 23 compresses the stream 20 to a pressure that can be compressed between about 25 bar(a) and about 70 bar(a) to produce a first compressed stream 24. The first compressed stream 24 is thereafter introduced into a first main heat exchanger 25 where it is cooled at the cold end of first main heat exchanger 25.

[0024] Stream 22 is further compressed by a turbine loaded booster compressor 26. After removal of the heat of compression by preferably, an after cooler 28, such stream is yet further compressed by a second booster compressor 29 to a pressure that can be in the range from between about 20 bar(a) to about 60 bar(a) to produce a second compressed stream 30. Second compressed stream 30 is then introduced into first main heat exchanger 25 in which it is partially cooled to a temperature in a range of between about 160 and about 220 Kelvin and is subsequently introduced into a turboexpander 32 to produce an exhaust stream 34 that is introduced into the air separation unit 50. As can be appreciated, the compression of stream 22 could take place in a single compression machine. As illustrated, turboexpander 32 is linked with first booster compressor 26, either directly or by appropriate gearing. However, it is also possible that turboexpander 32 be connected to a generator to produce electricity that could be used on-site or routed to the grid.

[0025] After the first compressed stream 24 has been cooled within main heat exchanger 25, it is expanded in an expansion valve 45 into a liquid and divided into liquid streams 46 and 48 for eventual introduction into the distillation column unit 50. Expansion valve 45 could be replaced by a liquid expander to generate part of the refrigeration.

[0026] The aforementioned components of the feed stream 10, oxygen and nitrogen, are separated within a distillation column unit 50 that consists of a higher pressure column 52 and a lower pressure column 54. It is understood that if argon were a necessary product, an argon column could be incorporated into the distillation column unit 50. Higher pressure column 52 operates at a higher pressure than lower pressure column 54. In this regard, lower pressure column 54 typically operates at between about 1.1 to about 1.5 bar(a).

[0027] The higher pressure column 52 and the lower pressure column 54 are in a heat transfer relationship such that a nitrogen-rich vapor column overhead extracted from the top of higher pressure column 52 as a stream 56 is condensed within a condenser-reboiler 57 located in the base of lower pressure column 54 against boiling an oxygen-rich liquid column bottoms 58. The boiling of oxygen-rich liquid column bottoms 58 initiates the formation of an ascending vapor phase within lower pressure column 54. The condensation produces a liquid nitrogen containing stream 60 that is divided into streams 62 and 64 that reflux the higher pressure column 52 and the lower pressure column 54, respectively to initiate the formation of descending liquid phases in such columns.

[0028] With respect to reflux of higher pressure column 52, in addition to stream 62, the stream 6 of the refrigerant is introduced into higher pressure column 52 after having been valve expanded by a valve 65 to a suitable pressure.

[0029] Exhaust stream 34 is introduced into the higher pressure column 52 along with the liquid stream 46 for rectification by contacting an ascending vapor phase of such mixture within mass transfer contacting elements 66 and 68 with a descending liquid phase that is initiated by reflux stream 62. This produces a crude liquid oxygen column bottoms 70 and the nitrogen-rich column overhead that has been previously discussed. A stream 72 of the crude liquid oxygen column bottoms is expanded in an expansion valve 74 to the pressure of the lower pressure column 54 and introduced into such column for further refinement. Second liquid stream 48 is passed through an expansion valve 76, expanded to the pressure of lower pressure column 54 and then introduced into lower pressure column 54.

[0030] Lower pressure column 54 is provided with mass transfer contacting elements 78, 80, 82, 84 and 85 that can be trays or structured packing or random packing or other known elements in the art. As stated previously, the separation produces an oxygen-rich liquid column bottoms 58 and a nitrogen-rich vapor column overhead that is extracted as a nitrogen product stream 86. Additionally, a waste stream 88 is also extracted to control the purity of nitrogen product stream 86. Both nitrogen product stream 86 and waste stream 88 are passed through a subcooling unit 90. Subcooling unit 90 subcools reflux stream 64. Part of reflux stream 64, as a stream 92, may optionally be taken as a liquid product and a remaining part 93 may be introduced into lower pressure column 54 after having been reduced in pressure across an expansion valve 94.

[0031] After passage through subcooling unit 90, nitrogen product stream 86 and waste stream 88 are fully warmed within first main heat exchanger 25 to produce a warmed nitrogen product stream 95 and a warmed waste stream 95. Warmed waste stream 96 may be used to regenerate the adsorbents within prepurification unit 16. Part of the nitrogen product stream 95 is taken as stream 4 for liquefaction within central liquefier 3. In addition, an oxygen-rich liquid stream 98 is extracted from the bottom of the lower pressure column 54 that consists of the oxygen-rich liquid column bottoms 58. Oxygen-rich liquid stream 98 can be pumped by a pump 99 to form a pressurized oxygen containing stream 100. Part of the pressurized liquid oxygen stream 100 can optionally be taken as a liquid oxygen product stream 102. The remainder 104 can be fully warmed in first main heat exchanger 25 and vaporized to produce an oxygen product stream 106 at pressure.

[0032] The stream 6 of the refrigerant will increase the production of liquid products, for example oxygen-rich liquid stream 102. Air separation plant 2 could be of the same design as air separation plant 1 and the stream 7 of the refrigerant could be introduced into such plant in the same manner as stream 6 of the refrigerant. Additionally, part of the nitrogen product stream of such air separation plant 2 could also be feed to the central refrigeration system 3. In such case, plant refrigeration would be supplied by turboexpander 32 stream 24 within a liquid expander (in lieu of expansion valve 45) and introduction of the stream 6 of the refrigerant into higher pressure column 52. As can be appreciated, central refrigeration system 3 could be operated on an intermittent basis when it was desired to produce more liquid products. Another possibility might be that air separation plant 2 is designed without the turbine loaded booster arrangement of turboexpander 32 and second booster compressor 29. In such case, stream 7 of the refrigerant would be supplying all of the refrigeration requirements of air separation plant 2. Assuming the expansion valve 45 were replaced by a liquid expander, then stream 7 of the refrigerant would be supplying only part of the plant refrigeration requirements. A further possibility is to introduce the stream 7 of the refrigerant into the main heat exchanger of the second air separation plant.

[0033] With reference to FIG. 3, central refrigeration system 3 is illustrated that is a nitrogen liquefier in which nitrogen-rich vapor contained within part 4 of the nitrogen product stream 95 is compressed and cooled to generate the liquid and refrigeration for the cooling is generated through turbo expansion of another part of the nitrogen-rich vapor. Although there are various design that are possible for such liquefiers, in the specific liquefier illustrated in FIG. 3, part 4 of the nitrogen product stream 95 is compressed in a feed gas compressor 200 to a pressure in the range of 4.8 to 6.2 bara. A recycled stream 226 is then merged with stream 5 to form combined recycle stream 202. Stream 202 is further compressed in a primary recycle compressor 204 to a pressure in the range of 35 to 55 bara. Compressors 200 and 204 may form part of the same machine, may employ multiple stages of intercooled compression and/or may be of centrifugal, axial or of positive displacement type.

[0034] After compression, combined recycle stream 202 is then subdivided into a warm expansion stream 206 and a remaining high pressure stream 208. Warm expansion stream 206 is turbo-expanded in turbine 210 to a pressure marginally above the pressure of stream combined recycle stream 202 and is then directed to an intermediary temperature location of a primary heat exchanger 212.

[0035] Remaining high pressure stream 208 is first cooled in primary heat exchanger 212 to an intermediate temperature, between the warm and cold end temperatures thereof, in the range of between about 150K and about 180 K. Thereafter, a cold expansion stream 214 is extracted and expanded in turboexpander 216 to a pressure marginally above the pressure of combined recycle stream 202. This stream is then directed to the cold end of primary heat exchanger 212. The remaining fraction of stream 208, stream 216, is further cooled to a temperature below the critical temperature of nitrogen and preferably to a temperature marginally above the saturated vapor temperature of stream 6 of the refrigerant. Stream 216 exits primary heat exchanger 212 most likely in a sub-cooled, super-critical dense liquid like state. Stream 216 is then expanded in valve 218 or potentially a dense phase expander to an intermediary pressure and phase separated in vessel 220. The resulting vapor phase stream 222 is then combined with cold expansion stream 214, after expansion, to form combined stream 224. Combined stream 224 is warmed to ambient along with warm expansion stream 206 after expansion to form recycle stream 226 that is then recycled to the primary recycle compressor 204 as described. Alternatively stream 206, 214 and 222 could be directed to separate and distinct passages within exchanger 212. Such stream can then be combined as necessary.

[0036] Although the use of liquefied nitrogen as a transmission medium of refrigeration is preferred, there are other possibilities. For instance, a portion of the boosted air for air liquefaction could be combined after cooling with the cold end air streams which naturally exist in an air separation plant. Furthermore, it is possible to transfer the refrigeration to a secondary refrigerant/coolant such as a mixed gas refrigerant and then direct the same to the various air separation plants. If such other refrigerant streams were used, then they would be introduced into the various air separation plants in the main heat exchanger and recirculated back to the refrigeration system in closed recirculation loops. Alternatively, such refrigeration could be imparted to streams extracted from the main heat exchanger. The cooled stream could then be returned to the columns or the main heat exchanger.

[0037] The operation of a centralized refrigeration circuit can be integrated with the on-site liquid storage/tankage system. In particular, the liquid produced from the refrigeration system can be first sent to storage for later dispersal to plants as required. Alternatively, a liquid exchange type heat exchanger can be used to transfer the refrigeration medium into another medium. For instance, liquefied nitrogen can be vaporized against a condensing stream of pressurized oxygen. The liquefied oxygen can then be sent to storage or to the plants for sustaining refrigeration. Some of the liquid generated from a centralized refrigeration system can be directed to off-site use. If a liquefied fluid is sent to low pressure storage it will naturally be necessary to mechanically pump the fluid back into the various air separation plants.

[0038] It should be noted that an enclave can utilize multiple air separation plants of different types (they need not be duplicate processes). For instance, one plant can be designed to deliver a high pressure, high purity nitrogen stream while the other can be designed for only oxygen production. In both instances, a centralized refrigeration system can be used to supply refrigeration to both.

[0039] While the present invention has been described in reference to a preferred embodiment as will occur to those skilled in the art, numerous changes and additions and omissions can be made without departing from the spirit and the scope of the present invention as set forth in the appended claims.