US2285696A - Process for desulphurizing mineral oil distillates - Google Patents
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- US2285696A US2285696A US354188A US35418840A US2285696A US 2285696 A US2285696 A US 2285696A US 354188 A US354188 A US 354188A US 35418840 A US35418840 A US 35418840A US 2285696 A US2285696 A US 2285696A
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- C—CHEMISTRY; METALLURGY
- 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
- C10G21/00—Refining of hydrocarbon oils, in the absence of hydrogen, by extraction with selective solvents
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- C—CHEMISTRY; METALLURGY
- 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
- C10G67/00—Treatment of hydrocarbon oils by at least one hydrotreatment process and at least one process for refining in the absence of hydrogen only
- C10G67/02—Treatment of hydrocarbon oils by at least one hydrotreatment process and at least one process for refining in the absence of hydrogen only plural serial stages only
- C10G67/04—Treatment of hydrocarbon oils by at least one hydrotreatment process and at least one process for refining in the absence of hydrogen only plural serial stages only including solvent extraction as the refining step in the absence of hydrogen
- C10G67/0409—Extraction of unsaturated hydrocarbons
- C10G67/0418—The hydrotreatment being a hydrorefining
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- C—CHEMISTRY; METALLURGY
- 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
- C10G7/00—Distillation of hydrocarbon oils
- C10G7/08—Azeotropic or extractive distillation
Definitions
- This invention pertains to the treatmentof hydrocarbon oils for the removal of sulphur, andv V is particularly concerned with an improved proctreatment of-higher-boiling hydrocarbon frac-' tions;
- the low-boiling hydrocarbon fractions produced as-a result of the application of heat to higher boiling hydrocarbon oils orshales contain objectionable sulphur compounds, such as hydrogen sulphide, mercaptans, aliphatic and cyclic thioethers and thiophenes. Certain of these sulphur compounds are readily removed or rendered innocuous by simple methods of treatment, such as extraction with solvents or conversion into disulphides. Other sulphur compounds, particularly thiophene and the alkyl'thiophenes, are
- thiophenes is used to designate thiophene and its homologues.
- a further purpose is to decompose thiophenes in gasolines to hydrocarbons and H28 without chemically altering hydrocarbons, such as olefines which normally are affected by treatments of a severity sufficient to break down thiophenes.
- Another purpose is to eliminate thiophenes from" gasolines by a process capable of maintaining or raising the octane ratings and lead susceptibilities of the fuels.
- the bottom product is desulphurized, while the azeotrope is separated into ahydrocarbon liquid and solvent.
- the desulphurized bottom product and the overhead hydocarbon liquid are then combined (McKittrick U. S. 2,114,852).
- Azeotropical distillation presents a somewhat more favorable picture in that it enables separation by chemical classes, thus making possible the production of sulphur concentrates consisting predominantly of sulphur compounds and aromatic hydrocarbons.
- this method of distillation is not only expensive, in that it requires the vaporization of a large amount of selective solvent, but also is rather difiicult to control, inasmuch as the formation of the azeotropical mixture depends on a definite ratio of solvent to feed, which ratio changes with changes in the composition of thefeed.
- small fluctuations in the feed are liable to ofiset the balance between feed and solvent which must be maintained for proper operation, thereby causing sulphur compounds to go overhead, or unsaturates' to go into the bottom product.
- the resulting fat liquid While descending through the lower portion or the extraction tower, the resulting fat liquid is continually refluxed with a bottom reflux consisting of preferentially soluble vapors either by reboiling the fat solution or by introducing from the outside vapors recovered by stripping the fat solution in a separate stripper. In this manner, most absorbed gasoline distillate vapors other than aromatic hydrocarbons and sulphur compounds are expelled.
- the refluxed fat solution is then stripped to recover the absorbed portion of the distillate comprising most of the sulphur compounds originally contained in the feed but havinga low percentage of olefines, and to produce a lean solvent, the latter being returned to'the top of the extraction tower. Unabsorbed vapors are refluxed in the top portion of the distillation column leaving it overhead and are condensed. The sulphur content of the resulting condensate is greatly reduced in comparison with thatof the feed.
- the high sulphur distillate portion resulting from the stripping operation is now subjected to a chemical desulphurization treatment, 1. e., a treatment which removes thiophenes from hydrocarbons if thiophenes are contained in the original distillate.
- a chemical desulphurization treatment 1. e., a treatment which removes thiophenes from hydrocarbons if thiophenes are contained in the original distillate.
- Sulphuric acid eliminates thiophenes by absorbing them, probably by way of forming sulphonic acids.
- the catalytic methods the
- thiophenes are broken down to H28 and hydrO-.
- the benefits obtainable from the separation into 'a high sulphur-low oieflne fraction and a low sulphur-high olefine fraction are the greater the more-complete the separation is.
- the ideal condition is the one which leads to the formation of a sulphur concentrate containing all the thiophene and other sulphur compounds and no olefines, and an overhead fraction containing no sulphur and all the olefines. When this is achieved, desulphurization can be made substantially completewithout sustenance of any of the disadvantages.
- vapor phase extraction which distillate has a relatively broad boiling range, say of about 50-100 (1., a fair separation can be achieved.
- a California cracked distillate boiling from 89-150 C. (A. S. T. M.) and having a sulphur content of 317% was subjected to an extractive distillation with three'volumes of a 60/40 mixture of phenol and cresols in a 44 plate distillation column operated under a top reflux of 3:1. 81% of the feed was taken overhead. containing 33% sulphur; while 19% of the feed went into the bottom product which contained 2.1% sulphur. Better than 90% ofthe oleflnes were contained in the top product.
- gasoline's to be desulphurized are fractionally distilled into somewhat narrower are ;*:'C.' of 122 0., 131 c, 160C" 172,c. and. 200-210 C., respectively, these being the boiling fractions according to a plan which will be explained hereinafter.
- this curve has definite peaks at about 103, 132, 156, 178 and 195C. Likewisepoints of minimum sulphur contents between the peaks are found at about 118, 143, 166, 188 and 206 C. It may be stated at this point that most cracked gasolines containing thiophenes show similar sulphur peaks and valleys which normally liewithin 5? C. and more often within 2 or 3 C. of the temperatures herein shown..
- a flow diagram is shown illustrating a preferred form of our process.
- vaporized gasoline distillate having an A. S. T. M. end boiling point'ofaround 210 C. enters the system'through line Lo from a source not shown.
- the vapors are fractionally distilled in a battery of four fractionating towers Fir-F4 to produce five fractions.
- the distillation is so controlled that the A. S. T. M. boiling ranges of the several fractions overlap but little, and that their 90% A. S. T. M. boiling points temperatures halfway between the sulphur maximauand next succeeding minima indicated in Fig. .1.
- Each of thesefivefractions is now fed into one of the extractive distillation towers Ei-Es through lines L1-L5, respectively, the points of entrance of the several streams being about halfway between top and bottom of each tower.
- a high boiling selective solvent for aromatic hydrocarbons is fed to the extraction towers at a point somewhere below the top of each tower through lines 81-55.
- Each tower is equipped with a reboiler, and is so operated to eflect a maximum concentration of sulphur compounds in the bottom product, while causing non-aromatic hydrocarbons to go overhead. From eachtower emerges from the bottom a fat solvent rich in sulphur compounds and aromatic hydrocarbons, and a desulphurized overhead product.
- the several fat solvents are withdrawn through lines Ri-Rs, and are'combined in manifold M1,
- the combined fat solvent is heated in heater H1 and is fractionally distilled in column Fa to drive on absorbed sulphurcompounds and aromatic hydrocarbons, and to produce a lean solvent.
- the latter passes through bottom line Ls, cooler Cs and thence to manifold M2, which feeds lines 81-185.
- the overhead product from towers E1-Es are condensed in condensers C1-C5, a portion of the condensates being returned to the respective towers for reflux,,and the remainder being conductedthrough-lines ,Ki Ks to be collected in manifold M: and tank T1.
- Desulphurizer D contains adesulphurizing catalyst, such as alumina or bauxite, preferably containing about 5%20% of an oxide of chromium, molybdenum, tungsten, etc.
- the content of hydrogen .in the feed to the desulphurizer may conveniently' vary from about .5%-4% by weight.
- Suitable temperatures of reaction rangefrom about 350 C. to about 520 C. at pressures up to about 40 atmospheres, preferably about 10 to 20 atmospheres.
- fractions may be produced and not all of them need be-subjected to the extractive distillation. It may be desirable to pick .out one or two or more of these fractions, perhaps because they possess an unusually high sulphur. content,.or because the hydrocarbon content in a particular fraction is particularly valuable or for some other reason.
- a fraction may contain a high proportion of toluene, and it may be the aim to isolate substantially pure toluene.
- the bottom product resulting from the extractive distillation of this fraction would not be combined with similar bottom products of other fractions, and on the contrary, this particular bottom product would separately be processed, i. e., separated from the solvent by fractional distillation and then be desulphurized without being combined with other bottom products.
- Solvents suitable for my purposes are those which have preferential solvent powers for aromatics over parafllnic hydrocarbons, are substantially stable and inert under the conditions of the process, and have boiling temperatures substantially higher than the A. S. T. M. end boiling points of the distillates or distillate fractions to be desulphurized.
- suitable solvents may be phenol, cresylic acids, alkyl phenol mixtures, aniline, alkyl anilines, diphenylamine, ditolylamines; carbitols (diethylene glycol mono ethers) such as methyl, ethyl, propyl carbitols; chlorinated dialkyl ethers such as beta-beta-dichlorethyl ether; nitrobenzene, nitrotoluene, nitroxylenes; naphthols, alkyl naphthols, benzophenone, phenyl tolyl ketone, diphenylene ketone; alkyl phthalates, such as dimethyl 'phthalate; alkyl salicylates, such as methyl salicylateybenzyl alcohol, benz chlorides, i.
- carbitols diethylene glycol mono ethers
- chlorinated dialkyl ethers such as beta-beta-dichlorethyl
- benzyl, benzal, benzo chlorides e., benzyl, benzal, benzo chlorides; benzonitrile, diphenyl oxide, ditolyl oxide, hydroxv pyridine, nitropyridine, chlorinated pyridines, quinoline, isoquinoline, chlorinated quincline, hydroxy quinolines, -nitro quinoline, tetra hydro furfuryl alcohol, furfuryl alcohol, furfural,
- the mono glycerol ethers such as l-methoxy glycerol, 2-methoxy glycerol, l-ethoxy glycerol, 2-ethoxy glycerol, l-propoxy glycerol, 2-propoxy glycerol, l-isopropoxy glycerol, Z-isopropoxy glycerol;
- the glycerol di-ethers such as 1,2-dimethoxy glycerol, 1,3-di-methoxy glycerol, 1,2- di-ethoxy glycerol, 1,3-di-ethoxy glycerol, 1,2,-dipropoxy glycerol, 1,3-di-propoxy glycerol, 1,2-diisopropoxy glycerol, 'and 1,3-di-isopropoxy glycerol; the mixed di-glycerol ether esters, such as 2-methoxy glycerol
- solvent tobe used may vary between very wide limits.
- solventzfeed ratios '(by weight) ranging from .5 to maybe used.
- the extractive distillation fundamentally differs from the azeotropical distillation mentioned earlier, the latter depending for successful operation on an exact ratio, which in turn varies with variations in the feed and thus is diflicult to control.
- a pressure distillate obtained by cracking a California gas oil 'in a Dubbs cracking unit was fractionally distilled in a packed column (equivalent to 44 theoretical plates) under a 3:1 top
- the bot-- tom product contained only about 1.0% oleflnes (equal to about .2% of the total olefine content of thepriginal fraction), all the remaining olefines having been accumulated in the overhead product.
- the bottom product was now desulphurized by passing it in admixture with 4 niols hydrogen over an aluminacatalyst, at 500 C. under 20 atmosphere pressures, the contact time being 32 seconds.
- the resulting product was freed from H28 and the recovered distillate, after being freed from 1.3% of heavy ends had a boiling range as determined by analytical distillation of 30.6 C. to 126 C. It contained 79% toluene, .6% heavier hydrocarbons, the remainder being principally pentanes produced in the destruction of the thiophenes. Its sulphur content was .0l%, and its bromine number .2.
- distillate has an A. S. T. M. boiling range not broader than about 100 C.
- sorbed portion of the fraction and subjecting the recovered portion to a desulphurization treatment of: sufficient intensity to remove the dissolved sulphur compounds, said solvent having a boiling temperature substantially higher than the A. S. T. M. end boiling point of said fraction and being-chemically inert under the conditions of said extraction.
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Description
June 9, 1942.
2 Sheets-Shet 1 Filed Aug. 26, 1940 am BE F: +5 w $5 234 Non U U0 B F 8 v on lnvzmor: Clarznc z L. Dunn bg his A1rorn zq:
J1me 1942' c. DUNN I 2,285,696
PROCESS FOR DESULPHURIZING MINERAL OIL DISTILLATES Fild Aug. 26, 194g 2 Sheets-Sheet 2 S: J 54 I 1 r lnvznior: Clarznccz L. Dunn Patented June 9, 1942 UNITED. STATES PATENT OFFICE PROCESS FOR DESULPHURIZ'ING MINERAL OIL DISTILLATES Clarence L. Dunn, Berkeley, Calif., assignor to Shell Development Company, San Francisco, Calif., a corporation of Delaware Application August 26, 1940, Serial No. 354,188
1 5 Claims. (01. 196-13) This invention pertains to the treatmentof hydrocarbon oils for the removal of sulphur, andv V is particularly concerned with an improved proctreatment of-higher-boiling hydrocarbon frac-' tions;
The low-boiling hydrocarbon fractions produced as-a result of the application of heat to higher boiling hydrocarbon oils orshales contain objectionable sulphur compounds, such as hydrogen sulphide, mercaptans, aliphatic and cyclic thioethers and thiophenes. Certain of these sulphur compounds are readily removed or rendered innocuous by simple methods of treatment, such as extraction with solvents or conversion into disulphides. Other sulphur compounds, particularly thiophene and the alkyl'thiophenes, are
difficult to remove except by intensive methods .which concurrently destroy or remove unsaturated hydrocarbons, including aromatics. Since cracked distillates contain largeamountsof unsaturated hydrocarbons, such as aromatics, olefines and diolefines, these methods have heretofore been uneconomical, and have not been applied to the treatment of such distillates save when hydrogenation or a similar conversion of the unsaturated hydrocarbons was at the same time an object of the treatment. The sulphur compounds most difiicult to remove from pressure distillate without adversely affecting the yield 'or knock rating of the gasoline are those occurring in the upper ends ofthe gasoline boiling above about 140 C., and appear to be polymethyl and higher derivatives of thiophene.
In the present specification and claims, the word thiophenes is used to designate thiophene and its homologues.
It is an object of this invention to provide an efiectve. method for desulphuriz'mg hydrocarbon distillates without causing material losses of valuable hydrocarbons. A further purpose is to decompose thiophenes in gasolines to hydrocarbons and H28 without chemically altering hydrocarbons, such as olefines which normally are affected by treatments of a severity sufficient to break down thiophenes. Another purpose is to eliminate thiophenes from" gasolines by a process capable of maintaining or raising the octane ratings and lead susceptibilities of the fuels. An-
,other object is to carry out this desulphurization by a combination of steps, wherein the sulphur compounds are first concentrated in a portion of the distillate, and the resulting concentrate is subjected to a chemical process for desulphurizing, preferably one involving catalytic desulphuriz'ation. j 7
It has already been. suggested to fractionally distill gasoline distillates to; segregate low and high sulphur fractions, subjecting the high sulphur fraction toa desulphurization treatment such as sulphuric acid treatment, and then combining the low sulphur fraction and desulphurized fraction to produce the finished gasoline (Morrell U. S. 1,827,537) f Further, it has been suggested to subject suitable high sulphur fractions to azeotropical distillation in the presence of a polar solvent having preferential solvent power for the sulphur compounds, to produce a high sulphur bottom prod uct and a low sulphur azeotropic mixture. The bottom product is desulphurized, while the azeotrope is separated into ahydrocarbon liquid and solvent. The desulphurized bottom product and the overhead hydocarbon liquid are then combined (McKittrick U. S. 2,114,852).
Both the above processes, whi1e quitefefiective in thematter of desulphurizing in a limited number of .cases, possess certain disadvantages'which so far have prevented their widespread adoption.
For example, whenmerely fractionally distilling to producev sulphur concentrates which are de-.- sulphurized, one is still confronted withthe alternative of drastically desulphuriz'ing at the cost of high hydrocarbon losses, or instead, of mildly desul-phurizing for the the sake of minimizing losses. This is due to the fact that simple fractional distillation only separates according to boiling temperature and not according to chemical composition, with the result that the sulphur concentrates normally are highly contaminated with unsaturates which are normally responsible for the losses sustained upon desulphurization, as by formation of high-boiling polymers.
Moreover, it is usually difiicult or impractical to produce definite sulphur concentrates in commercial distillation units so that the benefits obtainable from the pre-fractionation are meager and normally -do not pay for the cost of the special fractional distillation.
, Azeotropical distillation presents a somewhat more favorable picture in that it enables separation by chemical classes, thus making possible the production of sulphur concentrates consisting predominantly of sulphur compounds and aromatic hydrocarbons. However, this method of distillation is not only expensive, in that it requires the vaporization of a large amount of selective solvent, but also is rather difiicult to control, inasmuch as the formation of the azeotropical mixture depends on a definite ratio of solvent to feed, which ratio changes with changes in the composition of thefeed. Thus small fluctuations in the feed are liable to ofiset the balance between feed and solvent which must be maintained for proper operation, thereby causing sulphur compounds to go overhead, or unsaturates' to go into the bottom product. Moreover, in order to make possible at all a bottom product substantially free of components other than sulphur compounds and aromatic hydrocarbons, it
is essential to utilize in the azeotropical distilin the treatment with sulphuric acid, olefines are polymerized and/or converted to sulphates, mercaptans are converted to disulphides, etc. As a result, acid consumption and losses of valuable bons, to an" extractive distillation or vapor phase extraction with a liquid polar solvent having preferential solvent power for the aromatic hydrocarbons, under conditions to cause the liquid solvent to flow down the distillation or extraction column and to dissolve thiophenes and aromatic hydrocarbons if the latter are present. While descending through the lower portion or the extraction tower, the resulting fat liquid is continually refluxed with a bottom reflux consisting of preferentially soluble vapors either by reboiling the fat solution or by introducing from the outside vapors recovered by stripping the fat solution in a separate stripper. In this manner, most absorbed gasoline distillate vapors other than aromatic hydrocarbons and sulphur compounds are expelled. The refluxed fat solution is then stripped to recover the absorbed portion of the distillate comprising most of the sulphur compounds originally contained in the feed but havinga low percentage of olefines, and to produce a lean solvent, the latter being returned to'the top of the extraction tower. Unabsorbed vapors are refluxed in the top portion of the distillation column leaving it overhead and are condensed. The sulphur content of the resulting condensate is greatly reduced in comparison with thatof the feed.
The high sulphur distillate portion resulting from the stripping operation is now subjected to a chemical desulphurization treatment, 1. e., a treatment which removes thiophenes from hydrocarbons if thiophenes are contained in the original distillate. Among the many methods which heretofore had been devised for desulphurizing hydrocarbon oils, only a few are capable of eliminating the thiophenes. Among them are treatment with a concentrated sulphuric acid; selective catalytic hydrogenation over alumina, bauxite, and similar catalysts; selective catalytic cracking over sulphur-immune hydrogenation catalysts, such as sulphides of nickel, molybdenum, etc.; reactions with CO in the presence of sulphur-immune hydrogenation catalysts, etc.
Sulphuric acid eliminates thiophenes by absorbing them, probably by way of forming sulphonic acids. In the catalytic methods, the
thiophenes are broken down to H28 and hydrO-.
hydrocarbons are high, octane rating of the gasoline is reduced, etc. Likewise in the catalytic treatments, progressive desulphurization normally causes increasing losses in yields of treated distillate ordepreciation of octanerating or both. This depreciation of octane rating is especially large in processes of the types involving selective, hydrogenation of sulphur compounds, which types'of processesare, on the other hand, desirable because they make possible longlife of the catalysts. 'Substantial losses in yields are usually experienced at higher temperatures, i. e., above about 400C.
The components of distillates which are responsible for these various drawbacks are primarily olefines, and by eliminating them prior to the desulphurization treatment, the disadvantages can largely be overcome.
In the vapor phase extraction process hereinbefore described, a fairly eiiicient separation can be achieved between aromatic hydrocarbons and thiophenes on the one hand and remaining hydrocarbons on the other hand. Thus it is possible to obtain a bottom product high in sulphur having greatly reduced olefine content. This bottom product-can now be drastically desulphurized, without incurring to any great extent any of the above-enumerated disadvantages.
The benefits obtainable from the separation into 'a high sulphur-low oieflne fraction and a low sulphur-high olefine fraction are the greater the more-complete the separation is. The ideal condition is the one which leads to the formation of a sulphur concentrate containing all the thiophene and other sulphur compounds and no olefines, and an overhead fraction containing no sulphur and all the olefines. When this is achieved, desulphurization can be made substantially completewithout sustenance of any of the disadvantages.
When subjecting a gasoline distillate to the:
vapor phase extraction, which distillate has a relatively broad boiling range, say of about 50-100 (1., a fair separation can be achieved. For example, a California cracked distillate boiling from 89-150 C. (A. S. T. M.) and having a sulphur content of 317%, was subjected to an extractive distillation with three'volumes of a 60/40 mixture of phenol and cresols in a 44 plate distillation column operated under a top reflux of 3:1. 81% of the feed was taken overhead. containing 33% sulphur; while 19% of the feed went into the bottom product which contained 2.1% sulphur. Better than 90% ofthe oleflnes were contained in the top product.
It is noteworthy that no such considerable separation can be achieved by azeotropical distillation of the same distillate having this relatively broad, boiling range.
Still better separation can be achieved, however, if the gasoline's to be desulphurized are fractionally distilled into somewhat narrower are ;*:'C.' of 122 0., 131 c, 160C" 172,c. and. 200-210 C., respectively, these being the boiling fractions according to a plan which will be explained hereinafter.
It has already been established that when gasoline distillates, such as cracked gasolines' which contain thiophenes, are fractionally distilled inan analytical precision distillation column into a large number of very narrow fractions, and the sulphur content of each fraction is determined, it is found that some of the'fractions have higher sulphur contents than others. When plotting, for example, the 50% A. S. T. M. distillationpoints of 1% fractions versus their sulphur contents, a curve is obtained such as the one shown in Fig. 1 of the drawings, which represents distribution of sulphur content in a cracked California gasoline containing a total of .87% sulphur. As will be noted, this curve has definite peaks at about 103, 132, 156, 178 and 195C. Likewisepoints of minimum sulphur contents between the peaks are found at about 118, 143, 166, 188 and 206 C. It may be stated at this point that most cracked gasolines containing thiophenes show similar sulphur peaks and valleys which normally liewithin 5? C. and more often within 2 or 3 C. of the temperatures herein shown..
Now then, in my preferred procedure, I frac tionally distill the thiophene-containing gasoline to produce sharp fractions whose boiling ranges have as little as possible overlap and are such that each includes at least one and preferably only one sulphur peak or maximum, and whose A.,S. T. M. 90% distillation points are about midway between the temperatures of their respective highest boiling sulphur maximum and the next succeeding sulphur minimum, i. e., 1-5"- C. of 122, 137, 160, 172 and 2002l0 C. These fractions, of which there are ingeneral not more than 5 to cover the entire normal distillation range of motor gasolines, or fewer to cover a narrower range such as that of an aviation gasoline, are then separately subjected tothe vapor phase extraction hereinbefore described, and the several sulphur concentrates which are obtained as a result are then desulphurized, either singly or in combination.
By producing the fractions having the above properties, I am able to effect in the subsequent vapor phase extraction a remarkably complete concentration of the refractory sulphur compounds in the bottom product, while retaining practically no olefines therein. No other known simple method affords a similar highly efficient degree of separation. Because of this high efficiency of separation, the yields of the bottom products are relatively small. This, of course, is desirable in that a minimum volume of distillate need be desulphurized, which enables saving of treating reagent or catalyst, as the case may be. Normally, the bottom product are less than of the fractions from which they are produced, although the yields willvary with the content of sulphur compounds and aromatic hydrocarbons. v 7
In Fig. 2 of the attached drawings, .a flow diagram is shown illustrating a preferred form of our process. vaporized gasoline distillate having an A. S. T. M. end boiling point'ofaround 210 C. enters the system'through line Lo from a source not shown. The vapors are fractionally distilled in a battery of four fractionating towers Fir-F4 to produce five fractions. The distillation is so controlled that the A. S. T. M. boiling ranges of the several fractions overlap but little, and that their 90% A. S. T. M. boiling points temperatures halfway between the sulphur maximauand next succeeding minima indicated in Fig. .1. Each of thesefivefractions is now fed into one of the extractive distillation towers Ei-Es through lines L1-L5, respectively, the points of entrance of the several streams being about halfway between top and bottom of each tower.
A high boiling selective solvent for aromatic hydrocarbons is fed to the extraction towers at a point somewhere below the top of each tower through lines 81-55. Each toweris equipped with a reboiler, and is so operated to eflect a maximum concentration of sulphur compounds in the bottom product, while causing non-aromatic hydrocarbons to go overhead. From eachtower emerges from the bottom a fat solvent rich in sulphur compounds and aromatic hydrocarbons, and a desulphurized overhead product. The several fat solvents are withdrawn through lines Ri-Rs, and are'combined in manifold M1, The combined fat solvent is heated in heater H1 and is fractionally distilled in column Fa to drive on absorbed sulphurcompounds and aromatic hydrocarbons, and to produce a lean solvent. The latter passes through bottom line Ls, cooler Cs and thence to manifold M2, which feeds lines 81-185. The overhead product from towers E1-Es are condensed in condensers C1-C5, a portion of the condensates being returned to the respective towers for reflux,,and the remainder being conductedthrough-lines ,Ki Ks to be collected in manifold M: and tank T1. I
The overhead product, from fractionator Fe passes through vapor line L-: and condenser C1 to storage tank T2. This. product which contains most of the sulphur compounds of the original gasoline distillate is now conducted through line La and heater Hz to catalytic desulphurizer D. Alternately the vapors from line L1 may go directly by way of lines L9 and L8 to desulphurizer D. A small amount of hydrogen is injected through line L9 into the stream of distillate or distillate vapors in line Ls at some point ahead of the desulphurizer.
Desulphurizer D contains adesulphurizing catalyst, such as alumina or bauxite, preferably containing about 5%20% of an oxide of chromium, molybdenum, tungsten, etc. The content of hydrogen .in the feed to the desulphurizer may conveniently' vary from about .5%-4% by weight. Suitable temperatures of reaction rangefrom about 350 C. to about 520 C. at pressures up to about 40 atmospheres, preferably about 10 to 20 atmospheres. V 7
During. passage over the catalyst, sulphur compounds are broken down to hydrocarbons and H28. Therefore, the resulting product isfrac-r tionally distilled in fractionating tower F8 to remove H28, and the remaininghydrocarbons, freed from HzS, emerge from the bottom of the fractionatorFa and pass through cooler Co to run-down tank T3, or, if desired, to tank T1, to beblended with the low sulphur overhead products from the extractive distillation.
Whilethe described flow diagram illustrates the essential points of our process, it does not indicate the positions of pumps, heat exchangers, many of the valves; coolers, heaters, etc. The placement of such'auxiliary equipment is within the skill of the designers of such equipment.
Moreover, it is understood that it is notessentialthat all five fractions be produced in the distillation batteries Fi-F4. Different numbers l-ethoxy,
of fractions may be produced and not all of them need be-subjected to the extractive distillation. It may be desirable to pick .out one or two or more of these fractions, perhaps because they possess an unusually high sulphur. content,.or because the hydrocarbon content in a particular fraction is particularly valuable or for some other reason. For example, a fraction may contain a high proportion of toluene, and it may be the aim to isolate substantially pure toluene. In such a case, obviously, the bottom product resulting from the extractive distillation of this fraction would not be combined with similar bottom products of other fractions, and on the contrary, this particular bottom product would separately be processed, i. e., separated from the solvent by fractional distillation and then be desulphurized without being combined with other bottom products.
Should it be desirable, as indicated above, to
isolate aromatic hydrocarbons such as toluene,
then the principles described in my copending application Serial No. 348,046, filed July 27, 1940, may be incorporated in this process.-
Solvents suitable for my purposes are those which have preferential solvent powers for aromatics over parafllnic hydrocarbons, are substantially stable and inert under the conditions of the process, and have boiling temperatures substantially higher than the A. S. T. M. end boiling points of the distillates or distillate fractions to be desulphurized. Thus suitable solvents may be phenol, cresylic acids, alkyl phenol mixtures, aniline, alkyl anilines, diphenylamine, ditolylamines; carbitols (diethylene glycol mono ethers) such as methyl, ethyl, propyl carbitols; chlorinated dialkyl ethers such as beta-beta-dichlorethyl ether; nitrobenzene, nitrotoluene, nitroxylenes; naphthols, alkyl naphthols, benzophenone, phenyl tolyl ketone, diphenylene ketone; alkyl phthalates, such as dimethyl 'phthalate; alkyl salicylates, such as methyl salicylateybenzyl alcohol, benz chlorides, i. e., benzyl, benzal, benzo chlorides; benzonitrile, diphenyl oxide, ditolyl oxide, hydroxv pyridine, nitropyridine, chlorinated pyridines, quinoline, isoquinoline, chlorinated quincline, hydroxy quinolines, -nitro quinoline, tetra hydro furfuryl alcohol, furfuryl alcohol, furfural,
the mono glycerol ethers such as l-methoxy glycerol, 2-methoxy glycerol, l-ethoxy glycerol, 2-ethoxy glycerol, l-propoxy glycerol, 2-propoxy glycerol, l-isopropoxy glycerol, Z-isopropoxy glycerol; the glycerol di-ethers, such as 1,2-dimethoxy glycerol, 1,3-di-methoxy glycerol, 1,2- di-ethoxy glycerol, 1,3-di-ethoxy glycerol, 1,2,-dipropoxy glycerol, 1,3-di-propoxy glycerol, 1,2-diisopropoxy glycerol, 'and 1,3-di-isopropoxy glycerol; the mixed di-glycerol ether esters, such as 2-methoxy glycerol, l-methoxy, 3- propoxy glycerol,- l -ethoxy, 2-isopropoxy glycerol.
The amounts of solvent tobe used may vary between very wide limits. Thus solventzfeed ratios '(by weight) ranging from .5 to maybe used. In this freedom of solventzfeed ratio, the extractive distillation fundamentally differs from the azeotropical distillation mentioned earlier, the latter depending for successful operation on an exact ratio, which in turn varies with variations in the feed and thus is diflicult to control.
The following example further illustrates my process:
A pressure distillate obtained by cracking a California gas oil 'in a Dubbs cracking unit was fractionally distilled in a packed column (equivalent to 44 theoretical plates) under a 3:1 top A. S. T. M. boiling range:
reflux to produce a fraction having the following properties:
C. '1. B. P 87 10%' 94.5 90% 108 F. B. P 11 1.2
Bromine number 55.5 (equivalent to about 50 %-55% oleflnes) Sulphur .76% (of which .74 was-thir ophene sulphur) Toluene content 10% (weight) Overhead Per cent toluene Per cent sulphur 08 1. i Bottom product 6. 42 79. 8
Thus 98% of the total sulphur was concentrated in thebottom product. Moreover, the bot-- tom product contained only about 1.0% oleflnes (equal to about .2% of the total olefine content of thepriginal fraction), all the remaining olefines having been accumulated in the overhead product. I
The bottom product was now desulphurized by passing it in admixture with 4 niols hydrogen over an aluminacatalyst, at 500 C. under 20 atmosphere pressures, the contact time being 32 seconds. The resulting product was freed from H28 and the recovered distillate, after being freed from 1.3% of heavy ends had a boiling range as determined by analytical distillation of 30.6 C. to 126 C. It contained 79% toluene, .6% heavier hydrocarbons, the remainder being principally pentanes produced in the destruction of the thiophenes. Its sulphur content was .0l%, and its bromine number .2.
From this distillate, substantially pure toluene could easily be recovered by distillation.
When combining: this distillate with the low sulphur overhead product obtained earlier, a blend was obtained which was doctor sweet and contained about .07% sulphur. Its octane rating and. lead susceptibility were better than those of the original high sulphur fraction.
' I claim as my'invention:
1. In the process of desulphurizing a hydrocarbon distillate containing organic sulphur compounds and oleflnes, the improvement comprising subjecting said distillate to a vapor phase extraction with a liquid selective solvent having preferential solvent powers for aromatic hydrocarbons under conditions to produce a fat solvent containing absorbed portions of the distillate preferentially soluble in said solvent including sulphur compounds, and an overhead residual vapor of low sulphur content containing the major portion of said" olefines, said residual vapor being substantially free from said solvent solvent refluxing both the fat refluxing both the fat solvent andresidual vapors, the former with vapors obtained by'boiling the fat solvent, condensing the refluxed unabsorbed vapors, stripping the refluxed fat solvent to recover the absorbed portion of the distillate and subjecting the resulting recovered portion to a desulphurization treatment, of sufficient intensity to remove the dissolved sulphur compounds, said solvent having a boiling temperature substantially higher than the AS. T. M. end boiling point of said distillate, and being chemically inert under the conditions of said extraction.
2. The process of claim 1 wherein said distillate has an A. S. T. M. boiling range not broader than about 100 C.
. 3. The process of claim 1 wherein the extraction is an extractive distillation. q
4. The process of claim 1 wherein said desulphurization treatment of the recovered portion comprises treatment with a concentrated sulphuric acid under conditions to absorb sulphur compounds in the acid. l
5. The processed claim 1 whereinsaid solvent consists essentially of phenols.
6. In the process of desulphurizing a hydrocarbondistillate containing thiophenes and oleflnes, the improvement comprising subjecting said distillate to a vapor phase extraction with a liquid selective solventhaving preferential solvent powers for aromatic hydrocarbonsunder conditions to produce a fat solvent containing absorbed portions of the distillate preferentially soluble in said solvent including thiophenes, and an overhead residual vapor of low sulphur content-containing the major portion of said olefines, said residual vapor being substantially free from said solvent refluxing both thefat solvent and residual vapors, the former with vapors obtained by boilingthe fat solvent, condensing the refluxed unabsorbed vapors, stripping the refluxed fat solvent to recover the absorbed portion of the distillate and subjecting the resulting recovered portion to a desulphurization treatment of suificient intensity to remove thiophenes,. said solvent having a boiling temperature substantially higher than the A. S. T. M. end boiling point of said distillate, and being chemically inert under the conditions of said extraction.
7. The process of claim 6 wherein the desulphurization treatmentof said recovered portion comprises passing said portion over a sulphurimmune hydrogenation catalyst at a temperature between 350-520 C.
8. The process of claim 6 where the desulphurization treatment of said recovered portion comprises passing said portion admixed with .5%- 4% hydrogen over an oxidev of alumina at a temperature between 350-520 C. under a superatmospheric pressure below 40 atm.
9. In the process of desulphurizing a hydrocarbon distillate containing organic sulphur compounds and olefines, the improvement comprising subjecting said distillate to a vapor phase extraction with a liquid selective solvent having preferential solvent powers for aromatic hydrocarbons under conditions to produce a fat solvent containing absorbed portions of the distillate preferentially soluble in said solvent including sulphur compounds and an overhead residual vapor of low sulphur content containing the major portion of said olefines, said residual vapor being substantially free from said solvent and residsaid distillate and being chemically inert under the conditions of said extraction.
10. In the process of desulphurizing a hydrocarbon distillate containing organic sulphur compounds and olefines, which distillate upon analytical fractional distillation into a great number of narrow fractions shows a sulphur content versus boiling temperaturecurve having deflnite maxima and minima, the improvement-comprising fractionally distilling said distillate to produce at least one sharp fraction including a sulphur maximum, the 90% A. S. T. M. boiling point of which fraction is i5 C. of the temperature half-way between the temperature'at which this maximum and the next succeeding minimum occurs, subjecting said fraction to a vapor phase extraction with a liquid selective solvent havingpreferential solvent power for aromatic hydrocarbons under conditions to produce a fat solvent containing absorbed portions of said fraction preferentially soluble in said solvent including sulphur compounds, and an overhead residual vapor of low sulphur content containing a major portion of the'oleflnes contained in said fraction, said residual vapor being substantially'free from said solvent refluxing both the fat solvent and residual 'vapors, the former with vaporsv obtained by boiling the fat solvent, condensing the refluxedunabsorbed vapors, stripping the refluxed fat solvent to recover .the 'ab-. sorbed portion of the fraction and subjecting the recovered portion to a desulphurization treatment of: sufficient intensity to remove the dissolved sulphur compounds, said solvent having a boiling temperature substantially higher than the A. S. T. M. end boiling point of said fraction and being-chemically inert under the conditions of said extraction. 1
11. In the process-of desulphurizing a hydrocarbon distillate containing organic sulphur compounds and olefines, which distillate upon analytical fractional distillation into a great number of narrow fractions shows a sulphur content versus boiling temperature .curve having definite maxima and minima, the improvement comprising fractionally dist ssaid distillate to produce at least one sharp-fraction including one and only one sulphur maximum, the 90% ual vapors, the former with vapors obtained by 7 A. S. T. M. boiling point of said fraction being 15 C. of the temperature halfway betweenrthe temperatures at which the maximum and the next succeeding minimum occurs, subjectingsaid fraction to a vapor phase extraction with a liquid selective solvent having preferential solvent power for aromatic hydrocarbons under conditions to producea fat solvent containing absorbed portions, of said fraction'preferentially solublein said solvent including sulphur compounds, and an overhead residual vapor of low sulphur content containing a major portion of the olefines contained in said fraction,- said residual vapor being substantially free from said solvent refluxing both the fat solvent and residual vapors, the former with vapors'obta'ined by boiling the fat solvent, condensing the refluxed unabsorbed vapors, stripping the refluxed fat solvent to recover the absorbed portion of the fraction and subjecting the recovered portion to a desulphurization treatment of sufficient intensity to remove the dissolved sulphur compounds, said solvent having a boiling temperature substantially higher than the A. S. T. M. end boiling point of said fraction and being chemically inert under the conditions of said extraction.
12. In the process of desulphurizing a hydrocarbon distillate containing thiophenes and olefines, which distillate upon analytical fractional distillation into a great number of narrow fractions shows a sulphur content versus boiling temperature curve having definite maxima and min.- ima, the improvement comprising fractionally distilling said distillate to produce at least one sharp fraction including one and only one sulphur maximum, the 90% A. S. T. M. boiling point of said fraction being 15 C. of the temperaturehalfway between the temperatures at which the maximum and the next succeeding minimum occurs, subjecting said fraction to a vapor phase extraction with a liquid selective solvent having preferential solvent power for aromatic hydrocarbons under conditions to produce a fat solvent substantiallyfree from olefines and containing absorbed a portion of said fraction which is preferentially soluble in said solvent, and an overhead residual vapor substantiall free from thiophenes and said solvent, refluxing both the fat solvent and residual vapors, the former with vapors obtained by boiling the fat solvent, condensing the refluxed unabsorbed vapors, stripping the refluxed fat solvent to'recover the absorbed portion of the fraction and subjecting the recovered portion to a desulphurization treatment of suflicient intensity to remove thiophenes, said solvent having a boiling temperature substantially higher than the A. S. T. M. end boiling point of said fraction and being chemically inert under the conditions of said extraction.
13. In the process of desulphuri'zing a hydrocarbon distillate containing thiophenes and olefines, which distillate upon analytical fractional distillation into a great number of narrow fractions shows a sulphur content versus boiling temperature curve having deflnite maxima and minima, the improvement comprising fractionally distilling said distillate to produce at least one sharp fraction including one and only one sulphur maximum, the 90% A. S. T. M. boiling point of said fraction being i C. of one of thefollowing temperatures: 122 C., 137 C., 160 C., 172 C., 200-210 C., subjecting said fraction to a vapor phase extraction with a liquid selective solvent having preferential solvent power for aromatic hydrocarbons under conditions to produce a fat solvent substantially free from oleflnes and containing absorbed a portion of said fraction which is preferentially soluble in said solvent, and an overhead residual vapor substantially free from thiophenes and said solvent, refluxing both the fat solvent and residual vapors, the former with vapors obtained by boiling the fat solvent, condensing the refluxed unabsorbed' vapors, stripping the refluxed fat solvent to recover the absorbed portion of the fraction and subjecting the recovered portion to a desulphurization treatment of suflicient intensity to remove thiophenes, said solvent having a boil- A. S. T. M. end boiling point of said fraction and being chemically inert under the conditions of said extraction.
14. In the process of desulphurizing a normal boiling-range motor gasoline containing thiophenes and oleflnes, which gasoline upon analytical distillation into agreat number of narrow fractions shows a sulphur content versus boiling temperature curve having definite maxima and minima, the improvement comprising fractionally distilling said gasoline to produce flve sharp fractions whose 90% A. S. T. M. boiling points are 15 C. of 122 C., 137 C., 160 C., 172 C. and 200-210 C., respectively, individually subjecting said fraction to vapor phase extraction with a selective solvent having preferential solvent powers for aromatic hydrocarbons under conditions to produce as many fat solvents substantially free from oleflnes containing absorbed portions of said fractions which are preferentially soluble in said solvent, and overhead residual vapors substantially free from thiophenes and said solvent, refluxing said fat solutions and residual vapors, the former with vapors obtained ing temperature substantially higher than the by boiling the fat solvents, condensing and combining the refluxed unabsorbed vapors, combining the refluxed fat solutions, stripping the combined solution to recover the absorbed portions of said fractions, and subjecting the resulting recovered liquid to desulphurization treatment of suflicient intensity to remove thiophenes, said solvent having a boiling temperature substantially higher than the end boiling point of said gasoline and being chemically inert under .the conditions of said extraction.
15. In the process of desulphurizing a normal boiling range motor gasoline containing thiophenes and oleflnes, which gasoline upon analytical distillation into a great number of narrow fractions shows a sulphur content versus boiling temperature curve having definite maxima and minima, the improvement comprising fractionally distilling said gasoline to produce flve sharp fractions whose A. S. T. M. boiling points are :5 C. of 122 C., 137 C., C., 172 C. and 200-210 C., respectively, individually subjecting said fraction to vapor phase extraction with a selective solvent. having preferential solvent powers for aromatic hygirocarbons under conditions to produce as man fat solvents substantially free from olefines containing absorbed portions of said fractions which are preferentially soluble in said solvent, and overhead residual vapors substantially free from thiophenes and said solvent, refluxing said fat solutions and residual vapors, the latter with vapors obtained by boiling the fat solution, condensing and combining the refluxed unabsorbed vapors. combining the refluxed fat solutions, stripping the combined solution to recover the absorbed portions of said fractions, passing the resulting recovered liquid over a sulphur-immunehydrogenation catalyst in the presence of .5%4% by weight of hydrogen at a temperature of 350-520 C., whereby thiophenes are converted to hydrocarbons and hydrogen sulphide, separating thehydrogen sulphide from the hydrocarbons obtained in the catalytic treatment and combining the resulting hydrocarbon liquid with a condensate of said residual vapors, said solvent having a boiling temperature substantially higher than the end boiling point of said gasoline and being chemically inert under the conditions of said extraction.
CLARENCE 1.. pm.
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US354188A US2285696A (en) | 1940-08-26 | 1940-08-26 | Process for desulphurizing mineral oil distillates |
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US354188A US2285696A (en) | 1940-08-26 | 1940-08-26 | Process for desulphurizing mineral oil distillates |
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Cited By (9)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2428695A (en) * | 1945-02-12 | 1947-10-07 | Pure Oil Co | Hydrocarbon extraction process |
US2437357A (en) * | 1945-06-25 | 1948-03-09 | Union Oil Co | Solvent extraction of hydrocarbons |
US2439534A (en) * | 1945-04-07 | 1948-04-13 | Carbide & Carbon Chem Corp | Extraction of hydrocarbons |
US2608519A (en) * | 1949-11-29 | 1952-08-26 | Standard Oil Co | Desulfurization of olefinic naphtha |
US4265735A (en) * | 1979-12-21 | 1981-05-05 | Mobil Oil Corporation | ZSM-5 Zeolite catalyzes dialkyl disulfide conversion to hydrogen sulfide |
EP0711819A3 (en) * | 1994-11-11 | 1996-11-13 | Izumi Funakoshi | Process for recovering organic sulfur compounds from fuel oil and equipment therefor |
EP1167490A2 (en) * | 2000-06-23 | 2002-01-02 | Phillips Petroleum Company | Separation of olefinic hydrocarbons from sulfur-containing hydrocarbons by use of a solvent |
EP1294826A1 (en) * | 2000-02-11 | 2003-03-26 | GTC Technology Corporation | Process of removing sulfur compounds from gasoline |
EP2212406A1 (en) * | 2007-10-30 | 2010-08-04 | Saudi Arabian Oil Company | Desulfurization of whole crude oil by solvent extraction and hydrotreating |
-
1940
- 1940-08-26 US US354188A patent/US2285696A/en not_active Expired - Lifetime
Cited By (16)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2428695A (en) * | 1945-02-12 | 1947-10-07 | Pure Oil Co | Hydrocarbon extraction process |
US2439534A (en) * | 1945-04-07 | 1948-04-13 | Carbide & Carbon Chem Corp | Extraction of hydrocarbons |
US2437357A (en) * | 1945-06-25 | 1948-03-09 | Union Oil Co | Solvent extraction of hydrocarbons |
US2608519A (en) * | 1949-11-29 | 1952-08-26 | Standard Oil Co | Desulfurization of olefinic naphtha |
US4265735A (en) * | 1979-12-21 | 1981-05-05 | Mobil Oil Corporation | ZSM-5 Zeolite catalyzes dialkyl disulfide conversion to hydrogen sulfide |
EP0711819A3 (en) * | 1994-11-11 | 1996-11-13 | Izumi Funakoshi | Process for recovering organic sulfur compounds from fuel oil and equipment therefor |
US5753102A (en) * | 1994-11-11 | 1998-05-19 | Izumi Funakoshi | Process for recovering organic sulfur compounds from fuel oil |
EP1294826A4 (en) * | 2000-02-11 | 2003-05-14 | Gtc Technology Corp | Process of removing sulfur compounds from gasoline |
JP4828762B2 (en) * | 2000-02-11 | 2011-11-30 | ジーティーシー テクノロジー コーポレイション | Method for removing sulfur compounds from gasoline |
EP1294826A1 (en) * | 2000-02-11 | 2003-03-26 | GTC Technology Corporation | Process of removing sulfur compounds from gasoline |
US6551502B1 (en) | 2000-02-11 | 2003-04-22 | Gtc Technology Corporation | Process of removing sulfur compounds from gasoline |
EP1167490A3 (en) * | 2000-06-23 | 2003-01-29 | Phillips Petroleum Company | Separation of olefinic hydrocarbons from sulfur-containing hydrocarbons by use of a solvent |
US6802959B1 (en) | 2000-06-23 | 2004-10-12 | Conocophillips Company | Separation of olefinic hydrocarbons from sulfur-containing hydrocarbons by use of a solvent |
EP1167490A2 (en) * | 2000-06-23 | 2002-01-02 | Phillips Petroleum Company | Separation of olefinic hydrocarbons from sulfur-containing hydrocarbons by use of a solvent |
EP2212406A1 (en) * | 2007-10-30 | 2010-08-04 | Saudi Arabian Oil Company | Desulfurization of whole crude oil by solvent extraction and hydrotreating |
EP2212406A4 (en) * | 2007-10-30 | 2013-07-24 | Saudi Arabian Oil Co | Desulfurization of whole crude oil by solvent extraction and hydrotreating |
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