WO1999059943A1 - Olefin purification by adsorption of acethylenics and regeneration of adsorbent - Google Patents
Olefin purification by adsorption of acethylenics and regeneration of adsorbent Download PDFInfo
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- WO1999059943A1 WO1999059943A1 PCT/US1999/009213 US9909213W WO9959943A1 WO 1999059943 A1 WO1999059943 A1 WO 1999059943A1 US 9909213 W US9909213 W US 9909213W WO 9959943 A1 WO9959943 A1 WO 9959943A1
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- C10G—CRACKING HYDROCARBON OILS; PRODUCTION OF LIQUID HYDROCARBON MIXTURES, e.g. BY DESTRUCTIVE HYDROGENATION, OLIGOMERISATION, POLYMERISATION; RECOVERY OF HYDROCARBON OILS FROM OIL-SHALE, OIL-SAND, OR GASES; REFINING MIXTURES MAINLY CONSISTING OF HYDROCARBONS; REFORMING OF NAPHTHA; MINERAL WAXES
- C10G25/00—Refining of hydrocarbon oils in the absence of hydrogen, with solid sorbents
- C10G25/003—Specific sorbent material, not covered by C10G25/02 or C10G25/03
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- B01J20/30—Processes for preparing, regenerating, or reactivating
- B01J20/3085—Chemical treatments not covered by groups B01J20/3007 - B01J20/3078
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- B01J20/32—Impregnating or coating ; Solid sorbent compositions obtained from processes involving impregnating or coating
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- B01J20/3234—Inorganic material layers
- B01J20/3236—Inorganic material layers containing metal, other than zeolites, e.g. oxides, hydroxides, sulphides or salts
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- B01J20/30—Processes for preparing, regenerating, or reactivating
- B01J20/34—Regenerating or reactivating
- B01J20/3433—Regenerating or reactivating of sorbents or filter aids other than those covered by B01J20/3408 - B01J20/3425
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- B01J20/30—Processes for preparing, regenerating, or reactivating
- B01J20/34—Regenerating or reactivating
- B01J20/345—Regenerating or reactivating using a particular desorbing compound or mixture
- B01J20/3458—Regenerating or reactivating using a particular desorbing compound or mixture in the gas phase
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- C07—ORGANIC CHEMISTRY
- C07C—ACYCLIC OR CARBOCYCLIC COMPOUNDS
- C07C7/00—Purification; Separation; Use of additives
- C07C7/12—Purification; Separation; Use of additives by adsorption, i.e. purification or separation of hydrocarbons with the aid of solids, e.g. with ion-exchangers
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- C07—ORGANIC CHEMISTRY
- C07C—ACYCLIC OR CARBOCYCLIC COMPOUNDS
- C07C7/00—Purification; Separation; Use of additives
- C07C7/148—Purification; Separation; Use of additives by treatment giving rise to a chemical modification of at least one compound
- C07C7/152—Purification; Separation; Use of additives by treatment giving rise to a chemical modification of at least one compound by forming adducts or complexes
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- C10—PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
- C10G—CRACKING HYDROCARBON OILS; PRODUCTION OF LIQUID HYDROCARBON MIXTURES, e.g. BY DESTRUCTIVE HYDROGENATION, OLIGOMERISATION, POLYMERISATION; RECOVERY OF HYDROCARBON OILS FROM OIL-SHALE, OIL-SAND, OR GASES; REFINING MIXTURES MAINLY CONSISTING OF HYDROCARBONS; REFORMING OF NAPHTHA; MINERAL WAXES
- C10G70/00—Working-up undefined normally gaseous mixtures obtained by processes covered by groups C10G9/00, C10G11/00, C10G15/00, C10G47/00, C10G51/00
- C10G70/04—Working-up undefined normally gaseous mixtures obtained by processes covered by groups C10G9/00, C10G11/00, C10G15/00, C10G47/00, C10G51/00 by physical processes
- C10G70/046—Working-up undefined normally gaseous mixtures obtained by processes covered by groups C10G9/00, C10G11/00, C10G15/00, C10G47/00, C10G51/00 by physical processes by adsorption, i.e. with the use of solids
Definitions
- the field of this invention relates to use of heterogeneous adsorbents in purification of relatively impure olefins such as are typically produced by thermal cracking of suitable hydrocarbon feedstocks. More particularly, this invention concerns purification by passing an olefinic process stream, containing small amounts of acetylenic impurities, carbon oxides and/or other organic components, which are typically impurities in cracked gas, through a particulate bed of heterogeneous adsorbent comprising a metal supported on a high surface area carrier under conditions suitable for reversible adsorption of alkynes.
- Processes according to this invention are particularly useful where the olefin being purified is ethylene and/or propylene formed by thermal cracking of hydrocarbon feedstocks.
- olefins As is well known, olefins, or alkenes, are a homologous series of hydrocarbon compounds characterized by having a double bond of four shared electrons between two carbon atoms.
- the simplest member of the series, ethylene is the largest volume organic chemical produced today.
- olefins including ethylene, propylene and smaller amounts of butadiene are converted to a multitude of intermediate and end products on a large scale, mainly polymeric materials.
- olefins Commercial production of olefins is almost exclusively accomplished by pyrolysis of hydrocarbons in tubular reactor coils installed in externally fired heaters.
- Thermal cracking feed stocks include streams of ethane, propane or a hydrocarbon liquid ranging in boiling point from light straight-run gasoline through gas oil. Because of the very high temperatures employed, commercial olefin processes invariably coproduce significant amounts of acetylene and methyl acetylene. Required separation of the acetylene from the primary olefin can considerably increase the plant cost.
- the cracking represents about 25 percent of the cost of the unit, while the compression, heating, dehydration, recovery and refrigeration sections represent the remaining percentage of the total.
- This endothermic process is carried out in large pyrolysis furnaces with the expenditure of large quantities of heat, which is provided in part by burning the methane produced in the cracking process.
- the reactor effluent is put through a series of separation steps involving cryogenic separation of products such as ethylene and propylene.
- the total energy requirements for the process are thus very large, and ways to reduce it are of substantial commercial interest.
- it is of significant interest to reduce the amounts of methane and heavy fuel oils produced in the cracking processor and utilize them for other than for their fuel value.
- Hydrocarbon cracking is carried out using a feed which is ethane, propane or a hydrocarbon liquid ranging in boiling point from light straight-run gasoline through gas oil. Ethane, propane, liquid naphthas, or mixtures thereof are preferred feed to a hydrocarbon cracking unit. Hydrocarbon cracking is generally carried out thermally in the presence of dilution steam in large cracking furnaces which are heated, at least in part, by burning methane and other waste gases from the olefins process resulting in large amounts of NOx pollutants. The hydrocarbon cracking process is very endothermic and requires large quantities of heat per pound of product. However, newer methods of processing hydrocarbons utilize, at least to some extent, catalytic processes which are better able to be tuned to produce a particular product slate.
- the amount of steam used per pound of feed in the thermal process depends to some extent on the feed used and the product slate desired. Typically, steam pressures are in the range of about 30 lbs per sq in to about 80 lbs per sq in (psi), and amounts of steam used are in the range of about 0.2 pounds of steam per pound of feed to 0.7 pounds of steam per pound of feed.
- the temperature, pressure and space velocity ranges used in thermal hydrocarbon cracking processes depend to some extent upon the feed used and the product slate desired, which are well known and may be appreciated by one skilled in the art.
- cryogenic distillation liquid adsorption
- membrane separation membrane separation
- pressure swing adsorption in which adsorption occurs at a higher pressure than the pressure at which the adsorbent is regenerated.
- Cryogenic distillation and liquid adsorption are common techniques for separation of carbon monoxide and alkenes from gaseous mixtures containing molecules of similar size, e.g. nitrogen or methane.
- both techniques have disadvantages such as high capital cost and high operating expenses.
- liquid adsorption techniques suffer from solvent loss and need a complex solvent make-up and recovery system.
- U.S. Patent Number 4,019,879 and U.S. Patent Number 4,034,065 refer to use of high silica zeolites, which have relatively high selectivities for carbon monoxide, in the pressure swing adsorption method. However, these zeolites only have moderate capacity for carbon monoxide, and more particularly require very low vacuum pressures to recover the adsorbed gases and/or to regenerate the zeolite.
- U.S. Patent Number 4,717,398 describes a pressure swing adsorption process for selective adsorption and subsequent recovery of an organic gas containing unsaturated linkages from gaseous mixtures by passing the mixture over a zeolite ion- exchanged with cuprous ions (Cu I) characterized in that the zeolite has a faujasite type crystalline structure (Y).
- Kokai JP Number 50929 - 1968 describes a method of purifying vinyl compounds containing up to about 10 percent by weight of acetylenic compounds.
- acetylenic compounds were described as being adsorbed on an adsorption agent of 1-valent and/or 0-valent copper and/or silver supported on inert carrier such as ⁇ -alumina, silica or active carbon.
- German Disclosure Document 2059794 describes a liquid adsorption process for purification of paraffinic, olefinic and/or aromatic hydrocarbons with an adsorption agent consisting in essence of a complex of a copper (Cu I)-salt with an alkanolamine such as monoethanolamine, monoisopropanolamine, diethanolamine, triethanolamine and arylalkanolmines, and optionally in the presence of a glycol or polyglycol.
- an alkanolamine such as monoethanolamine, monoisopropanolamine, diethanolamine, triethanolamine and arylalkanolmines
- the product stream is contaminated with unacceptable levels of components of such agents absorbed in the hydrocarbon flow. While such contamination might be removable using an additional bed of silica gel, aluminum oxide or a wide-pored molecular sieve, this would involve additional capital costs, operation expenses and perhaps safety problems.
- Olefin-paraffin separations represent a class of most important and also most costly separations in the chemical and petrochemical industry. Cryogenic distillation has been used for over 60 years for these separations. They remain to be the most energy-intensive distillations because of the close relative volatilities. For example, ethane-ethylene separation is carried out at about -25°C and 320 pounds per square inch gage pressure (psig) in a column containing over 100 trays, and propane-propylene separation is performed by an equally energy-intensive distillation at about -30°C and 30 psig.
- psig pounds per square inch gage pressure
- Impurity refers to compounds that are present in the olefin plant feedstocks and products.
- Common impurities in ethylene and propylene include acetylene, methyl acetylene, methane, ethane, propane, propadiene, and carbon dioxide.
- acetylene, methyl acetylene, methane, ethane, propane, propadiene, and carbon dioxide Listed below are the mole weight and atmospheric boiling points for the light products from thermal cracking and some common compounds potentially found in an olefins unit. Included are some compounds which have similar boiling temperatures to cracked products and may be present in feedstocks or produced in trace amounts during thermal cracking. Mole Normal Boiling
- acetylenic impurities can be selectively hydrogenated and thereby removed from such product streams by passing the product stream over an acetylene hydrogenation catalyst in the presence of dihydrogen (molecular hydrogen, H2).
- these hydrogenation processes typically result in the deposition of carbonaceous residues or "green oil” on the catalyst which deactivates the catalyst. Therefore, acetylene hydrogenation processes for treating liquid or liquefiable olefins and diolefins typically include an oxygenation step or a "burn" step to remove the deactivating carbonaceous residues from the catalyst, followed by a hydrogen reduction step to reactivate the hydrogenation catalyst.
- an oxygenation step or a "burn" step to remove the deactivating carbonaceous residues from the catalyst
- a hydrogen reduction step to reactivate the hydrogenation catalyst.
- Patent Number 3,755,488 to Johnson et al. U.S. Patent Number 3,792,981 to Hettick et al, U.S. Patent Number 3,812,057 to Morgan and U.S. Patent Number 4,425,255 to Toyoda.
- U.S. Patent Number 3,912,789 and U.S. Patent Number 5,332,705 state that by using selected hydrogenation catalysts containing palladium, at least partial regeneration can be accomplished using a hydrogenation step alone at high temperatures (600° to 700°F) and in the absence of an oxygenation step.
- Selective hydrogenation of the about 2000 to 4000 parts per million of acetylenic impurities to ethylene is generally a crucial operation for purification of olefins produced by thermal steam cracking.
- Typical of a small class of commercially useful catalysts are materials containing very low levels of an active metal supported on an inert carrier, for example a particulate bed having less than about 0.03 percent (300 ppm) palladium supported on the surface skin of carrier pellets having surface area of less than about 10 m 2 /gm.
- acetylene, carbon monoxide and diolefins concentrations must be high enough to cover most active sites so none are left to adsorb ethylene.
- acetylene, carbon monoxide, methyl acetylene, and propadiene have bond strengths to palladium which are stronger than the ethylene to palladium bonds.
- operating temperature window is the delta of temperature between acetylene conversion to ethylene (typically in a range from about 100°F to about 150°F) and thermal runaway where all molecular hydrogen is converted and a large amount of the ethylene is converted to ethane (about 170°F to about 225°F). The wider the window, the safer is operation of the unit.
- unsaturated hydrocarbons e.g. olefins
- Processes of this invention comprise; passing a mixture comprising an unsaturated hydrocarbon compound of from 2 to about 8 carbon atoms, including at least one vinyl group, acetylenic and diolefin (alkadienes) impurities having the same or similar carbon content, and, optionally, saturated hydrocarbon gases through a particulate bed of adsorbent predominantly comprising a support material having high surface area on which is dispersed at least one metallic element selected from the group consisting of copper and silver, to effect, in the presence of an essentially dihydrogen- free atmosphere within the bed, selective and reversible adsorption and/or complexing of the contained acetylenic contaminants with the adsorbent, thereby obtaining purified effluent which contains less than a predetermined level of the acetylenic impurities; and, thereafter, regenerating
- Another aspect of special significance is the separation of acetylenic impurities from a gaseous mixture of ethylene or propylene containing small amounts of acetylene, i.e. less than about 5000 parts per million by weight of one or more acetylenic impurities, and advantageously provide purified product containing less than about 1 part per million by weight, and frequently even less than about 0.5 parts per million by weight of acetylenic impurities.
- the invention is a process for purification of olefins produced by thermal cracking of hydrocarbons which comprises: passing a gaseous mixture comprising at least about 99 percent by volume of an olefin having two to about four carbon atoms, and acetylenic impurities having the same or similar carbon content in an amount ranging upward from about 1 to about 1000 parts per million by volume, through a particulate bed of adsorbent predominantly comprising a support material selected from the group alumina, silica, active carbon, clay and zeolites, having a surface area in a range of from about 10 to about 2,000 square meters per gram as measured by the BET gas adsorption method, on which is dispersed at least one metallic element selected from the group consisting of copper and silver having particles of average diameter in a range of less than about 500 Angstroms, to provide an effluent stream from the bed; effecting, in the presence of an essentially dihydrogen- free atmosphere within the bed, selective and reversible
- the FIGURE is a schematic diagram of a preferred method for operating the process of this invention in the continuous mode, being arranged to provide sufficient reactants for the reactions and to maintain suitable reaction temperatures in accordance with the present invention.
- Processes of this invention are particularly suitable for use in purification of unsaturated hydrocarbon compounds of from 2 to about 8 carbon atoms which include at least one vinyl group, e.g. aliphatically unsaturated organic compounds generally produced by thermal cracking of hydrocarbons.
- Compounds of most interest with regard to purification by the method of the present invention have two to about eight carbon atoms, preferably two to about four carbon atoms, and more preferably ethylene or propylene.
- mixtures serving as a source of ethylene-containing feed for the process may contain about 1 to about 99 weight percent ethylene, about
- acetylenic impurities described in this invention are expressed by the formula
- R - C _ CH where R is hydrogen or a hydrocarbon group of up to 10 carbon atoms.
- the amount of hydrogen in the gaseous mixture should suitably be reduced to below 10 parts per million by weight, preferably below 2 parts per million by weight, and most preferably below 1 part per million by weight, prior to contact with the adsorbent.
- any mercury-containing, arsenic-containing, and sulfur-containing components, e.g. hydrogen sulfide, present in the gaseous mixture fed to the particulate bed of adsorbent should suitably be removed therefrom in any known manner in order to avoid the risk of poisoning the dispersed metal.
- the hydrocarbon mixture used in the process of the present invention is suitably a cracked gas from which the majority of the C5 and higher hydrocarbons have been removed.
- the gaseous mixture may thus comprise ethylene, propylene, butenes, methane, ethane, propane and butane. Small amounts of pentanes and pentenes can be tolerated in the gaseous mixture.
- the olefin in the gaseous mixture being purified is predominantly ethylene or propylene
- the gaseous mixture contains less than about 0.5 parts per million by volume of hydrogen and less than about 1 part per million by volume of mercury-containing, arsenic-containing, and sulfur-containing components, each calculated as the element
- the gaseous mixture, while passing through the bed is at temperatures in a range upward from about - 78°C to about 100°C, preferably in a range of from about - 35°C to about 65°C, and more preferably in a range of from about - 10°C to about 55°C.
- the gaseous mixture used in the process of the present invention may also comprise water and may optionally be saturated with water.
- a particulate bed of adsorbent comprising predominantly a support material having high surface area on which is dispersed at least one metallic element selected from the group consisting of copper, silver, iron, cobalt, nickel, zinc, ruthenium, palladium, platinum, and potassium, preferably at least one metallic element selected from the group consisting of copper and silver.
- Suitable adsorbents exhibit, in the presence of an essentially dihydrogen-free atmosphere within the bed, selective and reversible adsorption and/or complexing of the acetylenic impurities with the adsorbent.
- dispersed metal content is in a range of from about 0.01 to about 40 percent based on the total weight of the adsorbent.
- dispersed metal content is in a range of from about 0.01 to about 20 percent based on the total weight of the adsorbent.
- Suitable sources of the metallic elements include inorganic acid salts, organic acid salts and metallic oxides.
- Preferred sources of dispersed metal are soluble compounds, more preferred water soluble compounds such as metallic nitrates.
- Preferred for processes, according to this invention are adsorbents wherein the metallic element is dispersed on the high surface area support material in particles having average diameter in a range of less than about 500 Angstroms, preferably in a range of less than about 200 Angstroms, and more preferably in a range of less than about 100 Angstroms.
- Average diameters of small dispersed metal particles are measured by a method using the broadening of lines in an X-ray powder diffraction pattern. Such particle size measurement is discussed in Anthony R West's Solid State Chemistry and its Applications ⁇ p. 51 and p. 173- 175 John Wiley & Sons Ltd. ( 1984).
- a preferred class of adsorbents useful in processes according the invention comprises at least about 90 weight percent of a gamma alumina having surface area in a range of from about 80 to about 500 square meters per gram as measured by the BET gas adsorption method, and contains less than 500 parts per million by weight of a sulfur-containing component, calculated as elemental sulfur.
- the adsorbent which comprises at least about 90 weight percent of a gamma alumina having surface area in a range of from about 150 to about 350 square meters per gram as measured by the BET gas adsorption method, and wherein the metal dispersed on the support material is copper, and the absorbent has a copper content in a range of from about 0.01 to about 10 percent based on the total weight of the adsorbent.
- the adsorbent can optionally further comprise one or more elements selected from the group consisting of lithium, sodium, potassium, zinc, molybdenum, tin, tungsten, and iridium, dispersed on the support material.
- the adsorbent further comprises a member selected from the group consisting of lithium, sodium, potassium, zinc, molybdenum, and tin dispersed on the support material.
- the metal dispersed on the support material is advantageously at least one element selected from the group consisting of iron, cobalt, nickel, and palladium, and the absorbent has a dispersed metal content in a range of from about 0.05 to about 20 percent based on the total weight of the adsorbent.
- Another class of adsorbents useful for processes according to the invention comprises a dispersion of copper or silver, and one metallic element selected from the group consisting of lithium, sodium, potassium, zinc, molybdenum, tin, tungsten, and iridium, dispersed on the support material.
- adsorbents having copper metal dispersed on the support, and the absorbent has a copper content in a range of from about 0.05 to about 10 percent, more preferred in a range of from about 0.1 to about 5.0 percent, based on the total weight of the adsorbent.
- Capacity of an adsorbent is typically related directly to metal surface area. Any method which increases and/or maintains high metal surface area is, therefore, beneficial to achieving high acetylene adsorption capacity.
- Preferred for processes according to this invention are adsorbents having a dispersion value of at least about 10 percent, preferably in a range upward from about 20 percent to about 80 percent. Dispersion is a measure of the accessibility of the active metals on the adsorbent. Such dispersion methods are discussed in H. C. Gruber's, Analytical Chemistry, Vol. 13, p. 1828, (1962). The absorbents for use in this invention were analyzed for dispersion using a pulsed carbon monoxide technique as described in more detail in the Examples. Palladium-containing adsorbents having large dispersion values are desired because more of the palladium metal is available for reaction.
- Support materials are advantageously selected from the group consisting of alumina, silica, carbon, clay and zeolites
- Support materials are preferably in a range of from about 10 to about 2,000 square meters per gram as measured by the BET gas adsorption method.
- a preferred class of active carbons useful herein are materials disclosed in commonly assigned U.S. Patent No. 4,082,694 to Arnold N. Wennerberg and Thomas M. O'Grady, which patent is incorporated herein by reference. Such suitable active carbon products are produced from carbonaceous material by a staged temperature process which provides improved yield and processability during manufacture.
- a source of carbonaceous material such as crushed coal, coal coke, petroleum coke or a mixture thereof, is heated with agitation in the presence of a substantial weight ratio of potassium hydroxide at a first lower temperature to dehydrate the combination.
- the temperature is raised to a second higher temperature to activate the combination which is thereafter cooled and washed to remove inorganic matter and form a high surface area active carbon having a cage-like structure exhibiting micro-porosity, good bulk density and Total Organic Carbon Index.
- Active carbon products for use as supports preferably have an effective surface area greater than about 2,300 square meters per gram, and more preferably greater than about 2,700 square meters per gram, and most preferably above about 3,000 square meters per gram as measured by the BET method.
- Active carbon products for use as supports typically have a bulk density greater than about twenty-five hundredths gram per cubic centimeter, and preferably greater than about twenty-seven hundredths gram per cubic centimeter, and more preferably above about three- tenths gram per cubic centimeter.
- useful active carbon products preferably have a Total Organic Carbon Index greater than about 300, more preferably greater than about 500, and most preferably greater than about 700.
- the term "molecular sieve” includes a wide variety of positive-ion-containing crystalline materials of both natural and synthetic varieties. They are generally characterized as crystalline aluminosilicates, although other crystalline materials are included in the broad definition.
- the crystalline aluminosilicates are made up of networks of tetrahedra of Si ⁇ 4 and AIO4 moieties in which the silicon and aluminum atoms are cross-linked by the sharing of oxygen atoms.
- the electrovalence of the aluminum atom is balanced by the use of positive ions such as, for example, alkali-metal or alkaline-earth-metal cations.
- Zeolitic materials both natural and synthetic, useful herein, have been demonstrated in the past to have catalytic capabilities for many hydrocarbon processes.
- Zeolitic materials often referred to as molecular sieves, are ordered, porous, crystalline aluminosilicates having a definite structure, with large and small cavities interconnected by channels.
- the cavities and channels throughout the crystalline material are generally uniform in size, allowing selective separation of hydrocarbons. Consequently, these materials in many instances have come to be classified in the art as molecular sieves and are utilized, in addition to the selective adsorptive processes, for certain catalytic properties.
- the catalytic properties of these materials are also affected to some extent by the size of the molecules which are allowed to selectively penetrate the crystal structure, presumably to be contacted with active catalytic sites within the ordered structure of these materials.
- Crystalline aluminosilicates are the most prevalent and, as described in the patent literature and in the published journals, are designated by letters or other convenient symbols. Exemplary of these materials are Zeolite A (Milton, in U.S. Pat. No. 2,882,243), Zeolite X (Milton, in U.S. Pat. No. 2,882,244), Zeolite Y(Breck, in U.S. Pat. No. 3,130,007), Zeolite ZSM-5 (Argauer et al., in U.S. Pat. No. 3,702,886), Zeolite ZSM- II (Chu, in U.S. Pat. No. 3,709,979), Zeolite ZSM- 12 (Rosinski et al, in U.S. Pat. No. 3.832,449), and others.
- Zeolite A Molton, in U.S. Pat. No. 2,882,243
- Zeolite X Molton, in U.S. Pat. No. 2,882,24
- Manufacture of the ZSM materials utilizes a mixed base system in which sodium aluminate and a silicon-containing material are mixed together with sodium hydroxide and an organic base, such as tetrapropylammonium hydroxide and tetrapropylammonium bromide, under specified reaction conditions to form the crystalline aluminosilicate, preferably a crystalline metallosilicate exhibiting the MFI crystal structure.
- a mixed base system in which sodium aluminate and a silicon-containing material are mixed together with sodium hydroxide and an organic base, such as tetrapropylammonium hydroxide and tetrapropylammonium bromide, under specified reaction conditions to form the crystalline aluminosilicate, preferably a crystalline metallosilicate exhibiting the MFI crystal structure.
- a preferred class of molecular sieves useful according to the present invention are crystalline borosilicate molecular sieves disclosed in commonly assigned U.S. Patent No. 4,268,420, U.S. Patent No. 4,269,813, U.S. Patent No. 4,292,457, and U.S. Patent No. 4,292,458 to Marvin R Klotz, which are incorporated herein by reference.
- a preferred embodiment of the invention is an integrated olefin purification system including: one or more optional heat exchangers for controlling temperature of the gaseous feedstream to temperatures in a range from about -20°F to about 200°F, illustrated as feed exchanger 20 ; adsorption vessels containing particulate beds of a suitable solid adsorbent, illustrated as vessels 40 and 60 ; and means for analysis of feed and effluent streams, illustrated as on-line analytical system 80.
- a gaseous mixture containing less than about 500 parts per million by weight of the acetylene and carbon monoxide impurities formed by chemical conversions in commercial thermal cracking processes is, for example, ethylene fed from the overhead of a C2 distillation tower or intermediate storage (not shown) through conduit 22 and into feed exchanger 20 to control temperature during adsorption.
- Effluent from feed exchanger 20 flows through manifold 21 or, alternately, through valve 24 and manifold 42 , or valve 26 and manifold 62 , into one of two adsorption vessels 40 and 60 which contain beds of suitable solid adsorbent such as gamma alumina with 1.0 percent palladium based upon the weight of adsorbent.
- suitable solid adsorbent such as gamma alumina with 1.0 percent palladium based upon the weight of adsorbent.
- the gaseous mixture passes through the bed of particulate adsorbent at gas hourly space velocities in a range of from about 0.05 hours- 1 to about 20,000 hours- 1 and higher, preferably from about 0.5 to about 10,000 hours - 1 .
- compositions of the gaseous feed and effluent of each adsorption vessel is monitored by on-line analytical system 80. While levels of acetylenic impurities in the effluent of the adsorption vessel in purification service are in a range downward from a predetermined level, purified olefin from adsorption vessel 40 and/or adsorption vessel 60 flows through manifold 41 , valve 43 and/or manifold 61 and valve 63 , then through manifold 71 directly to pipeline for transportation of polymer grade ethylene, or to storage (not shown).
- purified olefin flowing through manifold 71 is diverted to flare (not shown) while that adsorption vessel is isolated from the process flow by means of valve 24 and valve 43 , or valve 26 and 63 , and thereafter the resulting bed of loaded adsorbent is treated to effect release of the contained acetylenic impurities from the adsorbent by hydrogenation.
- Suitable adsorbents have a capacity to treat from about 300 to about 40,000 pounds of olefin feed per pound of adsorbent where the olefin feed contains about 0.5 parts per million (ppm) acetylene. Approximately 5 x 10-4 pounds of acetylene to about 1 x 10-2 pounds are advantageously adsorbed per pound of adsorbent before regeneration is required.
- the time required for alternately treating the loaded adsorbent to effect release of the contained acetylenic impurities from the adsorbent by hydrogenation is provided by using two (as shown) or more independent adsorption vessels containing beds. Regenerations are advantageously performed according to this invention in three steps.
- the adsorption vessel which contains the loaded bed for example vessel 60
- vessel 60 is isolated from the process flow by means of valve 26 and valve 63 , and depressured through manifold 62 , valve 64 , and manifold 51 to suitable disposal, such as a flare (not shown).
- vessel 40 is isolated from the process flow by means of valve 24 and valve 43 , and depressurized through manifold 42 , valve 44 , manifold 51 to disposal.
- dry inert gas such as methane, ethane, or nitrogen, which is preferably free of carbon oxides, unsaturated hydrocarbons and hydrogen, is fed from, for example, a nitrogen gas supply system (not shown), through conduit 32 , valve 52 , and manifold 56 , into exchanger 30 to control temperature during regeneration.
- a nitrogen gas supply system not shown
- Effluent from exchanger 30 flows through manifold 31 and, alternately, through valve 38 and manifold 61 , or valve 58 and manifold 41 , into one of two adsorption vessels 40 and 60 , thereby purging gaseous hydrocarbons therefrom to disposal through manifold 62 , valve 64 , manifold 51 , valve 74 , and conduit 75 , or through manifold 42 , valve 44, manifold 51 , valve 74 , and conduit 75.
- a reducing gas stream predominantly containing hydrogen is fed from, for example, a hydrogen gas supply system (not shown) through conduit 34 , valve 54 , and manifold 56 , into exchanger 30 to control temperature during regeneration.
- Effluent from exchanger 30 flows through manifold 31 and, alternately, through valve 38 and manifold 61 or valve 58 and manifold 41 , into one of two adsorption vessels 40 and 60 to hydrogenate acetylene contained in the bed preferably to ethylene.
- Effluent from the adsorption vessel during hydrogenation flows therefrom to intermediate storage (not shown) through manifold 62 , valve 68 , and conduit 73 , or through manifold 42 , valve 44 , manifold 51 , valve 66 and conduit 73 .
- rates of temperature increase during the second stage of regeneration are preferably controlled to rates of less than about l l°C per minute (about 20°F per minute) while increasing the temperature in a range of from about 4°C to about 200°C (about 40°F to about 400°F).
- Pressures of the hydrogen-rich reducing gas during the second stage of regeneration are advantageously in a range from about 5 psig to about 500 psig. While the reducing gas is flowing through the adsorbent bed, effluent gas composition is periodically monitored with gas analyzer 80. Second stage regeneration is complete when C2+ hydrocarbon levels in the effluent gas from the bed have been reduced to C2+ hydrocarbon levels in the feed.
- Third stage regeneration involves purging all gaseous hydrogen from the adsorption vessel with an inert gas, e.g. nitrogen with or without a saturated hydrocarbon gas such as methane or ethane, while the vessel is at temperatures in a range upward from about 140°F.
- an inert gas e.g. nitrogen with or without a saturated hydrocarbon gas such as methane or ethane
- the effluent gas is free of hydrogen, the effluent is directed to flare through manifold 62 via valves 64 and 74 , or manifold 42 via valve 44 and valve 74.
- flow of inert gas at or below ambient temperature and about 5 to about 100 psig, cools the vessel to about ambient temperature thereby completing the regeneration process.
- Surface area of adsorbents can be determined by the Brunaur-Emmett-Teller (BET) method, or estimated by the simpler Point B method.
- Adsorption data for nitrogen at the liquid nitrogen temperature, 77 K are usually used in both methods.
- the Brunaur-Emmett-Teller equation which is well known in the art, is used to calculate the amount of nitrogen for mono-layer coverage.
- the surface area is taken as the area for mono-layer coverage based on the nitrogen molecular area, 16.2 square Angstroms, obtained by assuming liquid density and hexagonal close packing.
- the initial point of the straight portion of the Type II isotherm is taken as the completion point for the mono-layer. The corresponding amount adsorbed multiplied by molecular area yields the surface area.
- Dispersion and surface area of active metal sites was determined by carbon monoxide chemisorption using a Pulse Chemisorb 2700 (Micromeritics). In this procedure, approximately 4 gram samples were purged with helium carrier gas, calcined in air at 500°C for 1 hr, purged with helium, reduced in hydrogen at 500°C, purged with helium, and cooled to room temperature. The sample was treated with 49.5 percent carbon monoxide in helium and then dosed with 0.045 mL pulses of 49.5 percent carbon monoxide (CO), balance nitrogen, and the carbon monoxide uptake was measured by a thermal conductivity cell. Palladium dispersion values were calculated assuming one carbon monoxide molecule per palladium atom. Palladium loadings are weight percent palladium metal.
- the total pore volume is usually determined by helium and mercury densities or displacements. Helium, because of its small atomic size and negligible adsorption, gives the total voids, whereas mercury does not penetrate into the pores at ambient pressure and gives inter-particle voids. The total pore volume equals the difference between the two voids.
- Palladium on a high-surface-area ⁇ -A ⁇ C ⁇ is a preferred adsorbent for purification of olefins in accordance with this invention.
- any known technique for monolayer dispersion can be employed.
- the phenomenon of spontaneous dispersion of metal oxides and salts in monolayer or submonolayer forms onto surfaces of inorganic supports with high surface areas has been studied extensively in the literature (e.g., Xie and Tang, 1990).
- a 50 mL TEFLON-lined stainless steel pressure vessel was loaded with 31.99 gm of commercially available adsorbent (about
- pure ethylene (less than about 0.5 ppm acetylene) was introduced at flow rates of 280 to 300 mL/min from a supply at room temperature. Pure ethylene was allowed to flow through the vessel for 15 min after vessel pressure reached 110 psig, and thereafter the flow of pure ethylene was replaced with a feed mixture which contained 191 ppm acetylene in a balance of ethylene. During adsorption the flow rate of the acetylene/ethylene mixture was 110 mL/min and operating conditions of temperature and pressure were controlled to 110 psig and 20.5°C.
- acetylene was detected (less than about 0.5 ppm acetylene) breaking through the bed of adsorbent after a total of 28 L (1 atm and 21°C) of feed gas was treated.
- the adsorbent exhibited a capacity of about 0.12 mL of acetylene per mL of adsorbent.
- the vessel was depressurized to 1 atm and nitrogen was purged through the vessel for about 15 min.
- the vessel was again wrapped in heating tape and heated to 150°C.
- Adsorbent was regenerated using pure hydrogen at a flow rate of 250 mL/min at 60 psig in about 13 hours.
- This comparative example is to illustrate the essential role of transition/noble metal in acetylene captation by use of a pure gamma alumina support without any dispersed transition/noble metal.
- This experiment was carried out using Alcoa F-200 alumina in the form of 1/8" spheres.
- Another 50 mL TEFLON- lined pressure vessel was loaded with 21.98 gm (31.5 mL) of the Alcoa F-200 alumina, and the vessel was connected into a gas adsorption unit as in Example 1. Nitrogen was used tp purge the vessel and alumina bed which were then heated to 170°C (about 338°F) with a flow of hydrogen.
- a pretreatment hydrogen reduction was run at 15 psig and hydrogen flow rate of about 250 mL/minute. After 3.5 hours the hydrogen pretreatment was stopped by replacing the hydrogen flow with nitrogen flow. The vessel was allowed to cool to about room temperature and then the vessel was immersed in a water recirculating bath to maintain a constant temperature of about 22°C (about 72°F).
- pure ethylene ( ⁇ 0.5 ppm acetylene) was then introduced at a flow rate of from about 280 to about 300 mL/minute. After several minutes the ethylene pressure in the vessel was increased to 110 psig. Pure ethylene was allowed to flow through the vessel for another 90 minutes before switching to a gas feed mixture containing 191 ppm acetylene in a balance of ethylene.
- Flow rate of the acetylene/ethylene mix was 1 10 mL/minute, and the vessel was at 110 psig and 22°C (about 72°F). Gas effluent compositions were taken periodically, using an on-line gas chromatograph to determine when acetylene started breaking through the adsorbent bed. A least 17 ppm of acetylene was observed in the gas effluent after only 18 minutes had elapsed from the time the acetylene/ethylene flow was started.
- the alumina has virtually no captation capacity for acetylene (less than 0.01 mL of acetylene per mL of adsorbent), and that the acetylene captation observed in Example 1 was due to the palladium metal dispersed on the alumina support.
- This example includes several adsorption cycles to illustrate critical roles of the amount of active metal and its valence state on the carrier for acetylene adsorption from a feed gas mixture containing less than 500 ppm acetylene in a balance of ethylene.
- Adsorbent for this experiment was prepared by crushing, using a mortar and pestle, 1/8 inch spheres of gamma alumina, loaded with 14 percent by weight of NiO, to particle sizes in the range of 8 on 14 mesh.
- TEFLON-lined pressure vessel was loaded with 22.03 gm (31.6 mL) of the 14 percent NiO on gamma alumina, and the vessel was connected into a gas adsorption unit as in Example 1. Nitrogen was used to purge the vessel and bed of adsorbent which were then heated to temperatures in the range of from 140°C to 250°C with a flow of hydrogen. A pretreatment hydrogen reduction was run at 55 psig and hydrogen flow rate of about 250 mL/minute. After 3 hours the hydrogen pretreatment was stopped by replacing the hydrogen flow with nitrogen flow. The vessel was allowed to cool to about room temperature and then immersed in a water recirculating bath to maintain a constant temperature of about 21.5°C.
- pure ethylene ( ⁇ 0.5 ppm acetylene) was then introduced at a flow rate of from about 280 to about 300 mL/minute. After several minutes the ethylene pressure in the vessel was increased to 110 psig. Pure ethylene was allowed to flow through the vessel for another 90 minutes before switching to a gas feed mixture containing 191 ppm acetylene in a balance of ethylene.
- Flow rate of the acetylene/ethylene feed mixture was 1 14.5 mL/minute and pressure in the vessel was at 103 psig. Effluent compositions were taken periodically using an on-line gas chromatograph to determine when acetylene started breaking through the adsorbent bed. Only 16 minutes after starting flow of acetylene/ethylene feed, acetylene was observed in the effluent at about 11 ppm. Therefore, the NiO/alumina was not able to satisfactorily remove acetylene from the ethylene feed with the hydrogen reduction of only 3 hours.
- a second acetylene/ethylene adsorption was carried out in the same manor as the first adsorption described in this example. Acetylene was detected in effluent from the adsorbent bed by the very first on-line GC analysis indicating minimal acetylene adsorption capacity. Another 16 hour hydrogen reduction cycle was performed at 65 psig and 226°C. After stopping the hydrogen and purging the vessel with nitrogen, it was cooled to 9.5°C. A third acetylene/ethylene adsorption was carried out at 9.5°C and 100 psig. This time the Ni/A ⁇ adsorbent was able to remove all the acetylene from the ethylene feed that contained 243 ppm acetylene. The adsorption capacity was 0.0923 mL acetylene/mL of adsorbent.
- the adsorbent bed After a 14 hour regeneration using hydrogen at 65 psig, and temperatures varying from 200°C to 268°C the adsorbent bed underwent another ethylene/acetylene adsorption cycle.
- the adsorbent bed was held at 21.8°C using a water recirculating bath, and the feed gas contained 243 ppm acetylene in ethylene.
- Feed gas pressure was 103 psig and the gas flow rate was 1 12.2 mL/minute.
- Acetylene did not break through the adsorbent bed until about 1.5 hour after the acetylene/ethylene feed flow was started. This corresponded to about 0.02 mL acetylene adsorbed per mL of adsorbent.
- small amounts of butenes and butadiene were also detected in the effluent, indicating green oil was being formed using this 14 percent NiO on alumina adsorbent.
- This example includes several adsorption cycles to illustrate critical roles of temperature and pressure on adsorbent capacity for acetylene adsorption from a feed gas mixture containing less than 500 ppm acetylene in a balance of ethylene. These runs were conducted at various preselected temperatures and pressures using a Pd/A ⁇ adsorbent, and illustrated how significantly acetylene adsorption capacity was affected.
- the Pd/A ⁇ adsorbent (0.3 percent palladium by weight) was prepared as in Example 2.
- Temperature at which adsorption occurs is believed to have an effect on both the adsorption capacity and the extent of undesirable side reactions such as green oil formation or acetylene/ethylene decomposition.
- pressure has a minor effect on adsorption capacity of acetylene on another Pd/A1 2 Q 3 adsorbent (0.3 percent palladium by weight). Only a minimal increase in the adsorption capacity was observed with increasing gas pressure during the adsorption cycle.
- Tail gas which comprises 15 to 35 percent hydrogen, 0.1 to 5 percent ethylene, 100 to 500 ppm CO, and the balance methane, is more plentiful and less expensive relative to pure hydrogen at an olefins unit. This example illustrates that use of tail gas to regenerate an acetylene saturated adsorbent bed is as effective as pure hydrogen.
- a 31.96 gm (43 mL) of another Pd/Al 2 0 ⁇ adsorbent (0.3 percent palladium by weight) was reduced using pure hydrogen as in Example 1 , with the exception that the reduction temperature was held to 180°C, at 75 psig for 7 hours.
- a stream containing 191 ppm acetylene, balance ethylene gas was passed through the adsorbent bed at 110 psig.
- Acetylene adsorption capacity was 0.06 mL acetylene/mL adsorbent.
- the next regeneration cycle was done using a gas blend containing 21.32 mole percent hydrogen, 0.1440 mole percent ethylene, 0.101 mole percent carbon monoxide, with the balance being methane.
- Tail gas was introduced at a flow rate of about 200 mL/minute and 75 psig. Temperature was held at about 49°C (120°F) for the regeneration by immersing the adsorption vessel in a water bath. After about 16 hours, flow of tail gas was stopped, and nitrogen was used to purge the vessel for 30 minutes at about 49°C (120°F). Pure ethylene was then flowed through the vessel at 110 psig for about 1.5 hours at 1 10 mL/ minute flow. After this time, the 191 ppm acetylene/ethylene mixture was flowed through the reactor at 110 psig, 120°F, and 110 mL/minute flow rate.
- Tail gas was used again to regenerate the adsorbent bed at the same conditions as above, only that instead of 16 hours of regeneration, only 2.75 hours of regeneration was done.
- acetylene adsorption capacity was 0.089 mL acetylene/mL adsorbent, nearly the same as when a 16 hour regeneration was done. No deleterious green oil was formed when tail gas was used for regeneration, and the adsorption capacity actually increased compared to pure hydrogen.
- the test unit consisted of a down flow reactor vessel that contained 1 ft 3 of a palladium on gamma alumina adsorbent (0.32 percent palladium by weight).
- Polymer-grade ethylene which contained less than 1 ppm acetylene at 1800 psig, was the olefin feed.
- ambient temperature tail gas was used which contained about 42 percent hydrogen, 0.8 to 5 percent ethylene, 300 to 500 ppm carbon monoxide and the balance methane.
- the fresh adsorbent was reduced with a 110 lb/hr flow rate of tail gas at 63 psig for about 18 hours.
- Tail gas Regeneration was done using tail gas at ambient temperature and 63 psig. About 4 hours of tail gas flow through the bed at 110 lbs/hr was enough to regenerate the 1 ft 3 bed of adsorbent. Tail gas was then stopped, nitrogen was used to purge the unit for 1/2 hour, and the next ethylene/acetylene adsorption cycle started.
- the second ethylene/acetylene adsorption cycle was done under identical conditions as the first cycle above, except the feed flow rate was constant at 400 lbs/hr. After over 66,000 lbs of ethylene was treated, a small amount 0.06 ppm of acetylene started to break through the bed. This corresponds to an adsorption capacity of about 0.32 mL acetylene adsorbed per mL of bed .
- Cupric nitrate (Fischer 98.3 percent), 15.27 gm, was dissolved in 75.1 mL of deionized water.
- the blue-green solution was slowly added to 83.42 gm of dried Alcoa F-200 activated alumina spheres (1/16 inch) with stirring, using a magnetic stir bar and stir plate. Just enough solution was added to the alumina in order for it to reach it's wetness point.
- Wet adsorbent was then heated on a hot plate at low heat with constant stirring to remove excess moisture. The adsorbent was then transferred to a 250 mL round bottom flask connected to a vacuum line and heated to about 90°C under vacuum to further dry it.
- adsorbent was transferred to a clay crucible for calcination in air to 600°C for 12 hours using an electric muffle furnace. After allowing the adsorbent to cool to room temperature, it was removed from the furnace and stored in a vacuum desiccator. The adsorbent was a green color. Metals analyses indicated 4.1 percent copper by weight was on the alumina, and the depth of copper penetration into the pellet was about 1 mm. Analysis using XRD line broadening showed the supported copper particles to be around 30 Angstroms. BET surface area of the alumina spheres was over 220 m /gm.
- a bed of about 43 mL (31.35 gm) of the calcined 4.1 percent CuO/ Al 2 0 ⁇ adsorbent was placed in the 50 mL stainless steel vessel between glass wool plugs.
- the vessel was attached to the adsorption unit as described in Example 1. Electric heat tape and insulation were wrapped around the vessel while purging the vessel with nitrogen at room temperature. It is important to reduce the copper oxide to copper metal. Where Cu (I) and/or Cu (II) are contacted with acetylene there is a likely possibility that explosive copper (I), (II) acetylides would be form.
- a mixture of hydrogen and nitrogen was then flowed through the vessel while monitoring the bed temperatures.
- Hydrogen concentration of the mixture was slowly increased so as to avoid a large exotherm in the bed during reduction of the copper.
- pure hydrogen was flowed through the reactor at room temperature.
- the vessel was then heated over a period of 3 hours to 200°C while flowing pure hydrogen through it.
- the bed was then held at 200°C in flowing hydrogen overnight (17 hours) before shutting off the hydrogen and purging the reactor with nitrogen.
- the bed was then cooled to room temperature.
- acetylene content in the effluent ethylene gas was analyzed periodically using an on-line gas chromatograph. No detectable acetylene ( ⁇ 0.5 ppm) was observed, indicating total adsorption of the feed acetylene onto the reduced Cu/ A ⁇ C ⁇ bed.
- the reduced C11/ AI 2 bed was purged with nitrogen for 1/2 hour before 214 ppm acetylene/ethylene feed was introduced to the vessel.
- An even higher gas flow rate was used (500 mL/min) in order to try to reach acetylene breakthrough in a 9 hour period. This flow rate was near the maximum this laboratory unit could produce.
- the acetylene adsorbed was now 1.27 mL /mL adsorbent. It was clear that the amount of Cu/ AI 2 Q 3 adsorbent in the bed would have to be decreased in order to reach breakthrough.
- the used adsorbent was then regenerated with pure hydrogen at 49°C, and 50 psig for 12 hours. After this regeneration, the reduced Q1/ AI 2 Q 3 was cooled to 10°C and then slowly oxidized by introducing small pulses of air into the nitrogen purge stream. The exotherms from the oxidation were kept to below 5°C. Eventually a continuous stream of air could be flowed through the vessel with no nitrogen diluent. After warming the vessel up to room temperature, the used adsorbent was removed. It was a dark gray color with a slight hint of red on some pellets. There was no shock sensitivity of these pellets, as was determined by grinding them into dust with a mortar and pestle. X-ray analysis showed no sign of copper acetylide phases in the used catalyst, only 30 Angstrom copper particles that were a mixture of metallic and oxidized copper were detected.
- the amount of adsorbent was reduced by blending 20 mL of the Cu/ Al 2 0 ⁇ adsorbent with 23 mL of inert alumina pellets. Adsorbent volume in the bed was reduced to less than half the amount in Example 8. This blended adsorbent bed was then reduced with pure hydrogen at 200°C for several hours, as described above. Once reduced, the Cu/ A1 2 was purged with nitrogen.
- Ethylene feed containing 214 ppm acetylene was then flowed through the bed at 25°C, 15 psig, at a flow rate of 497 mL/min. Effluent samples taken periodically indicated total acetylene removal from the feed. After about 9 hours on stream, the flow was stopped even though no acetylene breakthrough was observed. The C11/ AI 2 O 3 had adsorbed 2.41 mL acetylene/mL adsorbent. After a 1/2 hour nitrogen purge, the adsorbent was regenerated with pure hydrogen at 49°C and 250 mL/min. flow at 50 psig. The hydrogen regeneration was stopped after 14.7 hours and a nitrogen purge was introduced to the unit.
- a second adsorption cycle was then begun at the maximum feed gas flow possible, 560 mL/min, of ethylene feed containing 214 ppm acetylene. Process conditions were otherwise the same, at 25°C and 15 psig. Again, no acetylene breakthrough was observed after 9 hours of flow. The acetylene adsorption capacity was over 2.7662 mL acetylene/mL adsorbent! Clearly the bed would need to be diluted again with alumina in order to achieve breakthrough.
- Ethylene feed containing 214 ppm acetylene was then flowed through the reduced Cu/ A ⁇ C ⁇ bed at 500 mL/min at 15 psig and 25°C. No acetylene breakthrough was observed until 8.5 hours later when about 1 ppm acetylene broke through the bed.
- Hydrogen regeneration was carried out at 49°C and 50 psig, for 23 hours at a flow rate of 250 mL/min. After regeneration the vessel was purged with nitrogen before starting another acetylene/ethylene adsorption cycle. Ethylene feed containing 214 ppm acetylene was used at a higher flow rate of 558.5 mL/min, at 15 psig and 25°C. Acetylene breakthrough was again observed after several hours on stream, and the resulting acetylene capacity was 1.98 mL acetylene/mL adsorbent. This cycle demonstrated that regeneration with hydrogen, according to the invention, does indeed regenerate an acetylene saturated, reduced Cu/ Al 2 0 ⁇ bed.
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Priority Applications (7)
Application Number | Priority Date | Filing Date | Title |
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DE69919158T DE69919158T2 (en) | 1998-05-21 | 1999-04-28 | CLEANING OLEFINES BY ADSORPTION OF ACETYLENE COMPOUNDS AND REGENERATION BY THE ABSORBENT |
AU36689/99A AU3668999A (en) | 1998-05-21 | 1999-04-28 | Olefin purification by adsorption of acethylenics and regeneration of adsorbent |
CA002332504A CA2332504A1 (en) | 1998-05-21 | 1999-04-28 | Olefin purification by adsorption of acethylenics and regeneration of adsorbent |
EP99918876A EP1080056B1 (en) | 1998-05-21 | 1999-04-28 | Olefin purification by adsorption of acetylenics and regeneration of adsorbent |
AT99918876T ATE272598T1 (en) | 1998-05-21 | 1999-04-28 | PURIFICATION OF OLEFINS THROUGH ADSORPTION OF ACETYLENE COMPOUNDS AND REGENERATION OF THE ABSORBENT |
JP2000549563A JP2002515466A (en) | 1998-05-21 | 1999-04-28 | Olefin purification by adsorption of acetylenic substances and regeneration of adsorbent |
NO20005891A NO20005891L (en) | 1998-05-21 | 2000-11-21 | Olefin purification by adsorption of acetylene contaminants and regeneration of adsorbent |
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US09/082,707 US6124517A (en) | 1997-03-10 | 1998-05-21 | Olefin purification by adsorption of acetylenics and regeneration of adsorbent |
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EP2155375B1 (en) * | 2007-05-18 | 2019-05-01 | Shell International Research Maatschappij B.V. | A reactor system, an absorbent and a process for reacting a feed |
Also Published As
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ID27750A (en) | 2001-04-26 |
JP2002515466A (en) | 2002-05-28 |
ES2226379T3 (en) | 2005-03-16 |
ATE272598T1 (en) | 2004-08-15 |
DE69919158T2 (en) | 2005-08-04 |
PT1080056E (en) | 2004-12-31 |
NO20005891L (en) | 2001-01-22 |
MY120805A (en) | 2005-11-30 |
EP1080056A1 (en) | 2001-03-07 |
CA2332504A1 (en) | 1999-11-25 |
DE69919158D1 (en) | 2004-09-09 |
KR20010025081A (en) | 2001-03-26 |
KR100608474B1 (en) | 2006-08-09 |
NO20005891D0 (en) | 2000-11-21 |
US6124517A (en) | 2000-09-26 |
AU3668999A (en) | 1999-12-06 |
EP1080056B1 (en) | 2004-08-04 |
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