巴西专利BR112012031513B1 PROCESS TO PURIFY A NATURAL GAS

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专利摘要:
process for purifying a natural gas an exemplary embodiment can be a process for purifying a natural gas, by using first and second adsorbents. the process may include passing a feed, including natural gas, through the first adsorber, to obtain a purified natural gas product, regenerating the second adsorbor in a heating stage and regenerating the second adsorbent in a cooling stage. the heating stage may include separating a portion of the feed, comprised of a regeneration gas, passing the regeneration gas to a dryer to remove water, then heating the regeneration gas and passing the regeneration gas to the second adsorber to regenerate the second adsorber. the cooling stage may include expelling, at the initiation of cooling, at least part of a fluid present in the second adsorber into the dryer, to desorb water from a molecular sieve into the dryer, and then cooling the second adsorbent.
公开号:BR112012031513B1
申请号:R112012031513-7
申请日:2011-08-11
公开日:2020-03-17
发明作者:Leonid Bresler；Cedric Freeman；Keith R. Clark
申请人:Uop Llc；
IPC主号:

专利说明:

“PROCESS TO PURIFY A NATURAL GAS” [0001] This process generally refers to the purification of natural gas with one or more adsorbents and their purification. DESCRIPTION OF THE RELATED TECHNIQUE [0002] Natural gas, which can be obtained from offshore sources, can be purified by adsorption with a molecular sieve. Typically, open circuit regeneration is used due to the desire to adsorb more than one impurity, such as carbon dioxide. The use of closed-loop regeneration may be undesirable if other contaminants, such as water, are present due to excessive amounts of purge, which is the regeneration gas required to remove these contaminants from the regeneration circuit. Although closed circuit regeneration was proposed during the heating stage of adsorber regeneration, such closed circuit systems may fail to provide sufficient flexibility for variations in contaminant levels in natural gas. It is generally desirable to remove water and / or carbon dioxide from natural gas at levels that will not produce solids and / or hydrates during subsequent processing, such as liquefaction.
SUMMARY OF THE INVENTION
[0003] An exemplary embodiment can be a process for purifying a natural gas using first and second adsorbents. The process may include passing a feed including natural gas through the first adsorber, to obtain a purified natural gas product, regenerating the second adsorber in a heating stage and regenerating the second adsorbor in a cooling stage. The heating stage may include separating a portion of the feed, comprised of a regeneration gas, passing the regeneration gas to a dryer to remove water, heating the regeneration gas with a heater after leaving the dryer and passing the regeneration gas to the second adsorber to regenerate the second adsorber. In a cooling initiation, the cooling stage may include expelling at least part of a fluid present in the second adsorbent into the dryer, to desorb water from an adsorbent in the dryer, and cooling the second adsorber by circulating the regeneration gas bypassing the heater .
[0004] Another exemplary embodiment may be a process of regenerating with a heating stage and a cooling stage for an adsorber to purify a stream of natural gas. The process may include regenerating in the heating stage and in the cooling stage. The heating stage may include passing a regeneration gas, including a natural gas supply, to a dryer, to remove water, passing the dried regeneration gas to a heater and passing the heated regeneration gas to a adsorber being regenerated. The cooling stage may include passing the regeneration gas on a cooling initiation from the adsorber back to the dryer during regeneration, to regenerate the dryer.
[0005] Yet another exemplary embodiment may be a process for a two-stage regeneration of an adsorber, to remove one or more components from a natural gas. The process may include heating a adsorber with a regeneration gas, including a supply of natural gas in the first direction, and cooling the adsorber with the regeneration gas in the other direction. Typically, an initial fluid present in the adsorber in a cooling initiation is expelled to a dryer to regenerate a molecular sieve there.
[0006] The embodiments described here provide a dryer used to remove water during a heating stage to regenerate an adsorber. During the heating stage, materials or components, such as carbon dioxide, water and / or hydrogen sulfide, can be desorbed from the adsorber. In addition, the dryer, in turn, can be regenerated during a cooling regeneration stage using the fluid present in the adsorber at the beginning of cooling. As such, closed-loop regeneration can be used to minimize losses of product and / or natural feed gas used as a regeneration gas. Closed circuit regeneration can also minimize energy losses by reducing the amount of composition gas requiring compression during regeneration.
DEFINITIONS
[0007] As used herein, the term "chain" can include various hydrocarbon molecules, such as alkanes, alkenes, alkadiene and straight, branched or cyclic alkynes and, optionally, other substances, such as gas, e.g. hydrogen, or impurities, such as heavy metals and sulfur and nitrogen compounds. The stream may also include aromatic and non-aromatic hydrocarbons. The stream may also include aromatic and non-aromatic hydrocarbons. In addition, hydrocarbon molecules can be abbreviated Cl, C2, C3 ... Cn, where "n" represents the number of carbon atoms in one or more hydrocarbon molecules. In addition, a “+” or “-“ exponent can be used with an abbreviated notation of one or more hydrocarbons, p. eg, C3 + or C3-, which is even one or more of the abbreviated hydrocarbons. As an example, the abbreviation “C3 +” means one or more molecules of three carbon atoms and / or more.
[0008] As used herein, the term “zone” can refer to an area, including one or more items of equipment and / or one or more sub-areas. Equipment items may include one or more reactors or reactor vessels, heaters, exchangers, tubes, pumps, compressors and controllers. In addition, an item of equipment, such as a reactor, dryer or vessel, may also include one or more zones or sub-areas.
[0009] As used herein, the term "rich" can mean an amount of at least generally 50% and, preferably, 70%, by mol, of a compound or class of compounds in a stream.
[00010] As used herein, the term "substantially" can mean an amount of at least generally 50% and, preferably, 70 mol%, of a compound or class of compounds in a stream.
[00011] As used herein, the term "substantially" can mean an amount of at least generally 80%, preferably 90% and, optimally, 99 mol%, of a compound or class of compounds in a chain.
[00012] As used herein, the terms "adsorbent" and "adsorbent" include, respectively, an absorbent and an absorber and refer to, but are not limited to processes such as absorption and / or adsorption.
[00013] As used herein, the term "gas" can include one or more gases, liquids and / or solids in the form of a suspension, such as an aerosol.
[00014] As used herein, the term "purified natural gas product" can refer to a natural gas that has passed through an adsorbent to remove, e.g. carbon dioxide and / or water, and includes a natural gas product, which has undergone subsequent processing, such as particulate filtration.
BRIEF DESCRIPTION OF THE DRAWING
[00015] Fig. 1 is a schematic representation of an exemplary device.
DETAILED DESCRIPTION
[00016] With reference to Fig. 1, an exemplary apparatus 10 for purifying natural gas may include a filter 20, a plurality of filters 40, a plurality of dryers 70, a plurality of adsorbers 120, a cooler 170, a separator (separator steam-liquid) 180, a compressor 220, another compressor 260, another cooler 280 and another separator 290. Generally, at least part of the equipment can be included in a heating regeneration circuit 60 during a heating regeneration stage and a regeneration circuit 250 during a cooling regeneration stage. Although apparatus 10 may include two dryers, that is, a first dryer 80 and a second dryer 90, and include three adsorbers, that is, a first adsorbent 130, a second adsorbent 140 and a third adsorbent 150, dryers and / or adsorbers additional can be used. Generally, each adsorber 130, 140 and 150 undergoes three stages, that is, an adsorption stage, a heating regeneration stage and a cooling regeneration stage. As shown, the process flow lines of the figures can be referred to, interchangeably, as, e.g. lines, tubes, feeds, chains, products, portions or parts.
[00017] A natural gas can be used as a supply 12 for apparatus 10. Typically, supply 12 may include one or more C1-C6 hydrocarbons, preferably one or more C1-C2 hydrocarbons. Generally, natural gas includes at least 70 mol% of one or more C1 and C2 hydrocarbons, such as methane and ethane and, preferably, at least 90%, optimally 95 mol%, of methane. In addition to hydrocarbons, natural gas can include nitrogen, carbon dioxide and water. Natural gas can include no more than 3 mol%, preferably no more than 2 mol% nitrogen, no more than 2 mol%, preferably no more than 1.0 mol%, more preferably not more than 0.5 mol% and, optimally, no more than 0.2 mol% carbon dioxide, based on moles of natural gas; and not more than 7500 ppm by volume, preferably not more than 500 ppm by volume of water, based on the volume of natural gas. A natural gas can be obtained from natural sources, such as one or more wells, or synthetic sources, such as one or more gasifiers or landfills.
[00018] Typically, feed 12 can be at a temperature of 10 oC to 70 oC, preferably 10 oC to 40 oC, and a pressure of 600 to 12000 kPa, preferably 600 to 6000 kPa. Typically, the pressure in the apparatus 10 can be relatively constant.
[00019] Feed 12 can be provided to a filter 20, which in this exemplary embodiment can be a coalescer 20. Coalescer 20 can remove liquids from feed 12, which can be in a gas phase. Generally, liquids leave coalescer 20 as a stream of condensate 22. The rest of the feed 12 can enter a line 24 and a part, typically a substantial portion, can enter via a line 26 in the third adsorber 150 of the plurality of adsorbers 120 and another part can enter a line 14, as described here before. The third adsorber 150 can remove water and carbon dioxide from the feed by entering the third adsorber 150.
[00020] The plurality of adsorbents 120, such as the third adsorbent 150, can contain any suitable adsorbent, or a combination of adsorbents having the desired selectivity for water and carbon dioxide. Suitable adsorbents may include one or more molecular sieves, activated carbons, activated clays, silica gels, activated alumines and combinations thereof, as described, e.g. in US 5,089,034. Molecular sieves include, for example, the various forms of silicoaluminophosphates and aluminophosphates, as described in US 4,440,871 and US 4,310,440.
[00021] Zeolites that can be used as adsorbents include chabazite, also referred to as zeolite D, clinoptilolite, erionite, faujasite, also referred to as zeolite X and zeolite Y, ferrierite, mordenite, zeolite A and zeolite P. Other zeolites that can be suitable for use can be those having a high silica content, i.e., those having silica to alumina ratios greater than 10. Exemplary zeolites are described, e.g. in US 4,061,724, US 4,073,865, US 4,775,396 and US 4,935,580.
[00022] It is often desirable to agglomerate a crystalline molecular sieve with a binder. Exemplary binders can include one or more metal oxides, clays, silica, aluminas, silica-alumines, silica-zirconites, silica-thories, silica-biliates, silica-titanias, silica-alumina-tories, silica-alumina-zirconia and a mixture from them. Clay binders may be preferred and exemplary clay binders may include atapulgite, kaolin, volclay, sepiolite, polygorkite, kaolinite, bentonite, montmorillonite, illite and chlorite.
[00023] The third adsorber 150 can be operated at any suitable temperature and pressure, as described above. The temperature during adsorption can be 0 oC to 70 oC, preferably 15 oC to 50 oC. Generally, the adsorption temperature is above the dew point of the hydrocarbon or the temperature of hydrate formation. Typically, the feed gas passes through the third adsorber 150 generally in a downward flow direction.
[00024] The purified natural gas product can leave the adsorber on one line 28. Line 28 can be divided into lines 30 and 32 and the purified natural gas product can pass through a plurality of filters 40, including a first filter 42 and a second filter 44, to remove one or more particulates having a diameter greater than, e.g. 10 microns, of the purified natural gas product. The filtered product gas can leave lines 46 and 48 through the respective filters 42 and 44 and be combined in a line 50. In another exemplary embodiment, filters 42 and 44 can be operated alternatively with one filter removing particles and the other filter offline. One part can be divided into a line 52, as described above, and another part can be recovered as a product in a line 54. The product gas can then be in a condition suitable for subsequent processes, such as liquefaction.
[00025] The portion of the filtered product gas, provided in "A" via line 52, can be combined with the recirculated regeneration gas from line 224, as described below, in line 56. The gas in line 14 and the gases combined in line 56 can be communicated with heating regeneration circuit 60 to regenerate one or more adsorbents. Thus, the regeneration gas can include the purified natural gas product from line 52, combined with the recirculated regeneration gas from line 224 and combined with a portion of the feed gas from line 14. Particularly, regeneration can occur in the heating regeneration 60 and in the cooling regeneration circuit 250. Subsequently, the gas can be combined in a line 58 and enter a first dryer 80 of the plurality of dryers 70. Each dryer 80 and 90 can independently have an adsorbent, such as a molecular sieve, as described above for the plurality of adsorbers 120. The first dryer 80 can remove water from the combined gas to provide a gas suitable for regeneration. Generally, the first dryer can reduce the amount of water to no more than 10 ppm by volume, preferably 0.1 ppm by volume of water, based on the volume of gas in line 82. Then, the gas can leave the first dryer 80 and enter line 82.
[00026] The regeneration gas of line 82 can enter heater 100 using any suitable heat source, such as an oven, an electric heater, a heat exchanger or any combination thereof. As an example, a heat exchanger can employ any suitable heating fluid stream 102, such as pressurized steam, which can be followed by a subsequent heater, such as an electric heater. The heated gas can escape through line 104 at a temperature of 120 to 320 oC, preferably 120 to 300 oC. The pressure is generally the same as described above.
[00027] The gas may enter the first adsorber 130 of the plurality of adsorbers 120, typically in the other or opposite direction, e.g. upward flow, such as gas entering the first adsorber 130 in the adsorption stage. During the heating stage, the gas regenerates the first adsorber 130 incrementally by raising the temperature over the time of the first adsorber 130 typically until a predetermined temperature setpoint is reached. Once the desired elevated temperature is reached, non-condensable contaminants, such as carbon dioxide and / or water, are released from the adsorbent. Other components can also be desorbed, such as hydrogen sulfide. Generally, part of the feed 12 can be used as a regeneration gas due to the high temperature of the regeneration and the comparable high level of carbon dioxide circulating in the heating regeneration circuit 60. Often, the gas can enter the adsorber 130 in a generically direction of upward flow.
[00028] Gas including contaminants can leave the first adsorber 130 and enter line 160 for cooler 170, which can be a single air cooler 170, optionally followed by another exchanger, such as a process water or cooling. The air cooler 170 can lower the gas temperature by leaving the adsorber to condense heavier hydrocarbons and water. The gas can leave the air cooler 170 and enter line 172 to the separator 180.
[00029] The separator 180 may contain a evaporator 182 with a line 184 for draining condensate, typically including water, and a line 186 for removing gas. The gas in line 186 can be divided into a purge stream in a line 190 and the recirculating regeneration gas in a line 200. The gas in line 200 can be provided for suction from a compressor 220 and discharged into line 224. As discussed above, the discharged gas can be combined with the feed gas in line 14 and a filtered natural gas product in line 52 to comprise the regeneration gas.
[00030] Although the first adsorber 130 is passing through the heating regeneration stage, the second adsorbent 140 can undergo the cooling regeneration stage. Thus, once the second adsorber 140 passes through the heating stage, it can pass through the cooling stage to put the adsorbent in condition for an adsorption stage, as represented by the third adsorbor 150.
[00031] At the beginning of the cooling, the heated gas leaving the second adsorbent 140 can enter a distribution pipe passing through a line 162 and passing through an open valve 164 for "B". The gas can then pass through line 252 and through an open valve 254. Then the gas can pass through a compressor 260 of the cooling regeneration circuit 250. Once pressurized, the cooling gas can pass through line 262. for the second adsorber 140. Initially, a hot fluid, typically gas, may be present in the second adsorber 140 from the heating regeneration stage. The gas can pass down through the second adsorber 140 to line 264. In the exemplary embodiment, the gas entering the second adsorber 140 can be in the other or opposite direction, e.g. generally, downward flow, compared to the heating stage. Initially, a valve 276 can be closed and a valve 266 can be opened. The hot gas can pass through line 268 into the second dryer 90. Generally, the second dryer 90 is used to remove water from the purge gas during the heating regeneration stage. Pushing the hot gas from the second adsorber 140 can desorb water from the screen of the second dryer 90 into line 270. Then the gas can pass from line 178 into a cooler 280, which can be an air cooler 280. Optionally, the air cooler 280 can be followed by another exchanger, such as a process water or cooling exchanger.
[00032] Air cooler 280 can cool the gas that can pass to line 282 to separator 290. Separator 290 can contain a vaporizer 292 and provide condensate, typically water, on line 296 and gas passing to line 294 The gas can enter line 258 to compressor 260 and be recirculated in a closed circuit, minimizing material and energy losses.
[00033] When the gas is circulated, the gas cooled to a temperature of 10 to 70 oC, can pass from the second adsorber 140 to the second dryer 90. Once the second dryer 90 is cooled, valve 266 can be closed and the valve 276 can be opened to bypass the second dryer 90 allowing the gas to pass through a line 274 to accelerate the cooling of the second adsorber 140 and minimize energy consumption. Once the cooling stage is completed, the second adsorber 140 may be suitable for adsorption to produce a purified natural gas product.
[00034] Although individual equipment, such as heaters, coolers, vessels and rotating machines, is represented, it should be understood that such representations may indicate a plurality of such equipment of an optionally variable type. As an example, an air cooler depicted can indicate a plurality of coolers, such as air exchangers, process and cooling air exchangers.
[00035] Without further elaboration, it is believed that a person skilled in the art can, using the preceding description, use the present invention to its fullest extent. The foregoing preferred specific embodiments are, therefore, to be construed as merely illustrative and not limiting the rest of the description in any way.
[00036] In the foregoing, all temperatures are exposed in degrees Celsius and all parts and percentages are by weight, unless otherwise indicated.
[00037] From the foregoing description, a person skilled in the art can easily verify the essential characteristics of this invention and, without deviating from its spirit and scope, can make several changes and modifications of the invention to adapt it to various uses and conditions.

权利要求:
Claims (10)
[1]
1. Process to purify a natural gas using first and second adsorbents, characterized by the fact that it comprises: A) passing a feed (12) comprising natural gas through the first adsorbent (130) to obtain a purified natural gas product ( 28); B) regenerating the second adsorber (140) in a heating stage, in which the heating stage comprises: 1) separating a part of the feed comprised in a regeneration gas (58); 2) pass the regeneration gas to a dryer (80) to remove water; 3) heat the regeneration gas (82) with a heater (100) after leaving the dryer (80); and 4) passing the regeneration gas to the second adsorber (140) to regenerate the second adsorber; and C) regenerating the second adsorber (140) in a cooling stage, in which the cooling stage comprises: 1) expelling at the beginning of cooling at least a part of a fluid present in the second adsorbent to the dryer (80) to desorb water from a dryer adsorbent; and 2) cool the second adsorber (140) by circulating the regeneration gas bypassing the heater (100).
[2]
Process according to claim 1, characterized in that the natural gas comprises at least 70 mol% of at least one methane and ethane.
[3]
Process according to either of Claims 1 or 2, characterized in that the natural gas comprises at least 95 mol% of methane.
[4]
Process according to any one of claims 1 to 3, characterized in that the natural gas comprises not more than 2 mol% of carbon dioxide.
[5]
Process according to any one of claims 1 to 4, characterized in that the natural gas comprises not more than 0.5 mol% of carbon dioxide.
[6]
Process according to any one of claims 1 to 5, characterized in that the natural gas comprises no more than 7,500 ppm, by volume, of water.
[7]
Process according to any one of claims 1 to 6, characterized in that the natural gas comprises no more than 500 ppm, by volume, of water.
[8]
Process according to any one of claims 1 to 7, characterized in that the regeneration gas comprises at least 70 mol% of at least one methane and ethane.
[9]
Process according to any of claims 1 to 8, characterized in that the regeneration gas comprises at least 95 mol% of methane.
[10]
Process according to any one of claims 1 to 9, characterized in that the regeneration gas comprises not more than 2 mol% of carbon dioxide.

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法律状态:
2018-04-03| B06F| Objections, documents and/or translations needed after an examination request according art. 34 industrial property law|

2019-03-06| B06T| Formal requirements before examination|

2020-02-11| B09A| Decision: intention to grant|

2020-03-17| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 11/08/2011, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

申请号 | 申请日 | 专利标题

US12/859,166|2010-08-18|

US12/859,166|US8337593B2|2010-08-18|2010-08-18|Process for purifying natural gas and regenerating one or more adsorbers|

PCT/US2011/047318|WO2012024135A2|2010-08-18|2011-08-11|Process for purifying natural gas and regenerating one or more adsorbers|

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