US1847625A - High vacuum steam distillation - Google Patents

High vacuum steam distillation Download PDF

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US1847625A
US1847625A US259691A US25969128A US1847625A US 1847625 A US1847625 A US 1847625A US 259691 A US259691 A US 259691A US 25969128 A US25969128 A US 25969128A US 1847625 A US1847625 A US 1847625A
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steam
pressure
oil
solvent
high vacuum
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US259691A
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Edward G Ragatz
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Union Oil Company of California
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Union Oil Company of California
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    • CCHEMISTRY; METALLURGY
    • C10PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
    • C10GCRACKING 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
    • C10G7/00Distillation of hydrocarbon oils

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  • This invention relates to a process and ap paratus for the distillation at high vacuum, that is, at low absolute pressure. It relates, particularly, to a process and apparatus of high vacuum steam distillation wherein the steam is condensed at relatively high temperatures and relatively low pressures, the pressure being insufiicient of itself to condense the steam at said temperature. This is accomplished in the main by scrubbing the steam with a solvent to produce a watersolvent mixture whosevapor pressure s less than water and to produce a mixture whose vapor pressure is sufliciently low to cause condensation of steam at the pressures and temperatures employed.
  • the average temperature of the condensate would be 100 F. andperhaps higher. This is determined by the available cooling water temperature and the proportillation with steam without excessive ,cooling of the condensate, and, in fact, to use only such cooling water as is available at the plant.
  • the term available cooling water temperature will be defined as being that temperature which is obtainable by using a cooling water available at the plant where the process is operated when such cooling water is used in conventional methods either by direct contact with the steam or by intermediate heat exchange.
  • the invention is directed to a high vacuum steam distillation whereby means is provided to condense the steam at available cooling water temperature by scrubbing it with a solvent which is cooled by available cooling water, and regeneration of the water-solvent mixture at a low absolute pressure, and reintroduction of the steam into the distilling system, thusto cause regeneration of the solvent at substantially the pressure of the system.
  • This invention is particularly directed to such a method and apparatus for high vacuum distillation below, approximately 25 1n. m. whereby the residual steam is scrubbed to form a solvent mixture which will have a vapor pressure at, or below 25 m. 111., the temperature of the condensate being obtained by means of available cooling water and the solvent mixture is regenerated at substantially the pressure of the system provided by the reintroduction of the regenerated steam into the system.
  • 1 is a charging line for liquid to be distilled, in this case lubricating oil stock.
  • the oil is fed to 1 under desired pressure.
  • Steam may be mixed with the oil if desired by injection through line 2.
  • the oil is heatedin coils 3 of furnace 4 and injected into still 6 through spray 5.
  • the backpressure on coils 3 is regulated by valve 3 Distillation of the oil occurs in still 6 with the aid of steaminjected through spray 8.
  • This steam as will be explained later, consists of steam regenerated from still 30, supplemented by make-up steam injected through line 10.
  • the unvaporized material is withdrawn through 11 by pump 12.
  • the vaporized material passes through mist separator 7', which returns 7 entrained liquid.
  • the vapor passes through line 13 into a series of fractionalcondensers 14, cooled by oil, steam or water, as the case may be.
  • the condensate is withdrawn through 17 into run-down tanks 18, from which liquid is withdrawn through 19.
  • run-down tanks 18, from which liquid is withdrawn through 19. As will be understood by those skilled in the arts, by positioning the still 6 and condensers 14 at barometric height, the material will be discharged without the aid of pumps.
  • the uncondensed material consisting substantially of steam or fixed gases or light volatile oils passes from the last condenser 14 through line 20 into the barometric condenser 21 where it meets a stream of solvent liquid introduced through 22.
  • the uncondensed material is withdrawn through 23 by the high vacuum pump 24.
  • the solvent-water mix-v steam is introduced through line 9 into the still 6, and steam is introduced into the system through 2 in addition to that through line 9.
  • Steam may build up in the system and bypassed through 39 by partial regulation of the valves 40 and 41, to be re-cycled through the cooler and into the condenser.
  • Lubricating oil stock is introduced into coil 3, together with steam and heated to about 600 F. and then introduced into still 6' where additional steam is added. Still 6 is operated at about 20 iii. m. absolute pressure and the ratio of the steam to the oil is such that the mixture passing 13 contains by volume ofthe steam, i. e. the partial pressureof the steam is 15 m. m. and the oil 5.
  • the barometric condenser In the barometric condenser it is scrubbed by a solvent such as a salt solution, andthe temperature and concentration andvolume depend on the back pressure of thesystem and a is the pressure in thestill minus the back pressure of the system.
  • the requisite concentration can be readily determined by anyone skilled in the art since it is that concentration which 'wouldgive a vapor pressure at 100 F., which will equal that necessary to maintain the requisite absolute pres sure in the still 6.
  • the mixture is withdrawn through 27 and introduced into still 30 where it is evaporated under vacuum, the steam generated being introduced into the still 6.
  • the vacuum in still 3 would, therefore, be equal to the pressure in still 6 plus the back pressure on still 30. That is, still 30 will be operated at a sufiicient pressure to pass the vapor into still 6.
  • the concentrated material is passed to the cooler 36.
  • a method of high vacuum steam distillation which comprises steam distilling oil under high vacuum, condensing the oil vapors, scrubbing the steam with a solvent, maintaining the temperature and concentration of the solvent mixture thus formed to maintain the mixture at a vapor pressure less than the vapor pressureof water at the temperature of the mixture and evaporating the water from the solvent mixture under a pressure, substantially that of the said steanrdistillation of the oil.
  • Method of steam distilling oil under high vacuum which comprises vaporizing oil with steam under high vacuum, condensing the oil vapors thus generated without condensing the steam, scrubbing said steam vapors witha solvent, maintaining the pressure of the solvent mixture below the vapor pressure of water at the temperature obtainable by use of available cooling water, evaporating the water from the solvent mixture under a pressure, substantially that of the said steam distillation of the oil.
  • Method of high vacuum steam distillation comprising distilling oil with steam under high vacuum, condensing the resulting oil vapors without condensing the. steam, scrubbing the steam with a solvent at a temperature not less thanthe available cooling water temperature and at an absolute pressure less than the vapor pressure of water at said cooling water temperature, removing the solvent water mixture, evaporating water from said solvent, re-introducing the regenerated steam into the, oil undergoing distillation, cooling said solvent by heat exchange with available cooling'water, and
  • a method of high vacuum steam distillation-Which comprises distilling oil at a low absolute pressure with steam, condensing the steam at a low absolute pressure by scrubbing the same with a liquid, evaporating the water from the mixture thus formed, re-introducing the evaporated water into the oil undergoing distillation and re-introducing the regenerated liquid to condense further steam in cyclic operation.
  • An apparatus for high vacuum distillation comprising a steam still, a condenser, means for maintaining high vacuumin the steam still and in the condenser, means for introducing a scrubbing liquid into the condenser, an evaporator, means for introducing the scrubbing liquid into the evaporator, means for introducing the regenerated steam from the evaporator into the steam still, means for withdrawing the scrubbing liquid from the evaporator, a cooler, means for passing the scrubbing liquid from the evaporator through the cooler and to the condenser.
  • a method of high vacuum distillation of oil which comprises steam distilling oil at a low absolute pressure, fractionally condensing the oil but not condensing the steam,

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  • Chemical & Material Sciences (AREA)
  • Oil, Petroleum & Natural Gas (AREA)
  • Engineering & Computer Science (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • General Chemical & Material Sciences (AREA)
  • Organic Chemistry (AREA)
  • Vaporization, Distillation, Condensation, Sublimation, And Cold Traps (AREA)

Description

March 1, 1932. RAGATZ 1,847,625
HIGH VACUUM STEAM DISTILLATION Filed March '7, 1928 INVENTOR. few/4w G. 161:;A1'Z
BY d p ATTORNEY.
Patented Mar. 1, 1932 UNITED 4 STATES PATENT. OFFICE EDWARD G. RAGATZ, OI LOS ANGELES, CALIFORNIA, ASSIGNOR TO. UNION OIL COM- IPANY OF CALIFORNIA, OF LOS ANGELES, CALIFORNIA, A CORPORATION OF CALI- FORNIA HIGH VACUUM STEAM ADISTILLATIOCN Application filed March 7,1928. Serial No. 259,691.
This invention relates to a process and ap paratus for the distillation at high vacuum, that is, at low absolute pressure. It relates, particularly, to a process and apparatus of high vacuum steam distillation wherein the steam is condensed at relatively high temperatures and relatively low pressures, the pressure being insufiicient of itself to condense the steam at said temperature. This is accomplished in the main by scrubbing the steam with a solvent to produce a watersolvent mixture whosevapor pressure s less than water and to produce a mixture whose vapor pressure is sufliciently low to cause condensation of steam at the pressures and temperatures employed.
It is well known that in ordinary vacuum distillation, the absolute pressure maintainable in the still is in part determined by the vapor pressure which exists at the terminal receiver immediately preceding the vacuum pump. Thus theminimum pressure mainof mercury, it is essential to provide means in the terminal receiver of condensing the steam at this'pressure and to maintain the pressure of the water in the receiver by sufliciently cooling the condensate so as to produce a vapor pressure below the desired pressure.
. However, in order to maintain the vapor pressure of the steam condensate such as to maintain this. very low vacuum, the water must be cooled to very low temperature. Thus at very low pressures in the neighborhood of 5 m. m. a temperature at the freezing point of waterwould be required. However, if
the steam is condensed by use of ordinary cooling water, the average temperature of the condensate would be 100 F. andperhaps higher. This is determined by the available cooling water temperature and the proportillation with steam without excessive ,cooling of the condensate, and, in fact, to use only such cooling water as is available at the plant. In further discussion, the term available cooling water temperature will be defined as being that temperature which is obtainable by using a cooling water available at the plant where the process is operated when such cooling water is used in conventional methods either by direct contact with the steam or by intermediate heat exchange.
In operating theprocess of this invention, the steam resulting after the condensation of the oil vapor, which is at very low pressure,
is scrubbed with a solvent and the solventwater mixture is evaporated under a high vacuum. T he steam which results from this distillation may be re-used in the process to produce a cyclic operation. By the re-use of the steam from the regenerating stills and boiler, a regeneration of the solvent-water. mixture at substantially the distillation pressure of the apparatus is made possible. This results in a low regeneration temperature. Additionally, since this low temperature distillation produces a regeneration material of relatively low temperature, the amount of cooling which isrequired before it may be reintroduced into the condenser, to scrub the steam, is diminished. In many operations, especially where cooling water. is a considerableitem of expense, this produces a considerable saving.
The invention is directed to a high vacuum steam distillation whereby means is provided to condense the steam at available cooling water temperature by scrubbing it with a solvent which is cooled by available cooling water, and regeneration of the water-solvent mixture at a low absolute pressure, and reintroduction of the steam into the distilling system, thusto cause regeneration of the solvent at substantially the pressure of the system. This invention is particularly directed to such a method and apparatus for high vacuum distillation below, approximately 25 1n. m. whereby the residual steam is scrubbed to form a solvent mixture which will have a vapor pressure at, or below 25 m. 111., the temperature of the condensate being obtained by means of available cooling water and the solvent mixture is regenerated at substantially the pressure of the system provided by the reintroduction of the regenerated steam into the system. r
The process and apparatus will be better understood by reference to the accompanying drawing which illustrates the specific embodiment, illustrative, but not limiting the invention.
The figure on the accompanying drawing shows a schematic form of one embodiment ofthe apparatus for carrying out the process of the invention.
In the drawing, 1 is a charging line for liquid to be distilled, in this case lubricating oil stock. The oil is fed to 1 under desired pressure. Steam may be mixed with the oil if desired by injection through line 2. 'The oil is heatedin coils 3 of furnace 4 and injected into still 6 through spray 5. The backpressure on coils 3 is regulated by valve 3 Distillation of the oil occurs in still 6 with the aid of steaminjected through spray 8. This steam, as will be explained later, consists of steam regenerated from still 30, supplemented by make-up steam injected through line 10. The unvaporized material is withdrawn through 11 by pump 12. The vaporized material passes through mist separator 7', which returns 7 entrained liquid. The vapor passes through line 13 into a series of fractionalcondensers 14, cooled by oil, steam or water, as the case may be. The condensate is withdrawn through 17 into run-down tanks 18, from which liquid is withdrawn through 19. As will be understood by those skilled in the arts, by positioning the still 6 and condensers 14 at barometric height, the material will be discharged without the aid of pumps.
The uncondensed material consisting substantially of steam or fixed gases or light volatile oils passes from the last condenser 14 through line 20 into the barometric condenser 21 where it meets a stream of solvent liquid introduced through 22. The uncondensed material is withdrawn through 23 by the high vacuum pump 24. The solvent-water mix-v steam is introduced through line 9 into the still 6, and steam is introduced into the system through 2 in addition to that through line 9., Steam may build up in the system and bypassed through 39 by partial regulation of the valves 40 and 41, to be re-cycled through the cooler and into the condenser.
As a specific example illustrating this process in its preferred embodiment, the following may be given:
Lubricating oil stock is introduced into coil 3, together with steam and heated to about 600 F. and then introduced into still 6' where additional steam is added. Still 6 is operated at about 20 iii. m. absolute pressure and the ratio of the steam to the oil is such that the mixture passing 13 contains by volume ofthe steam, i. e. the partial pressureof the steam is 15 m. m. and the oil 5.
The oil is condensed in condenser 14, and the residual steam passes to barometric condenser 21. V
In the barometric condenser it is scrubbed by a solvent such as a salt solution, andthe temperature and concentration andvolume depend on the back pressure of thesystem and a is the pressure in thestill minus the back pressure of the system. The requisite concentration can be readily determined by anyone skilled in the art since it is that concentration which 'wouldgive a vapor pressure at 100 F., which will equal that necessary to maintain the requisite absolute pres sure in the still 6. The mixture is withdrawn through 27 and introduced into still 30 where it is evaporated under vacuum, the steam generated being introduced into the still 6. The vacuum in still 3 would, therefore, be equal to the pressure in still 6 plus the back pressure on still 30. That is, still 30 will be operated at a sufiicient pressure to pass the vapor into still 6. The concentrated material is passed to the cooler 36.
. Inoperating with a salt. solution care must be taken to concentrate the salt solution in 30 not above that concentration which would cause crystallization'of the salt when cooled in cooler: 36. Since the limit of temperature and concentration are fixed by the requisite concentration in condenser 21 and that in 36, it will be frequently found advisable to circulate aportion of the liquid from 26 direetly into the cooler36, through line 39.
This will permit the maintenance of the requisite concentration and volume of the solution in 21 and also permit of sufficient evaporation in 30. v
While the specific example discloses the use of 20 m. in. it will be understood that absolute pressure may be lower as far as 1 or 2 m. m. or less, or above 25 m. m. as the case demands. The solvent may be either glycerine or any other liquid of relatively high boiling point and sutlicient water solubility. Salt such as calcium chloride or other materials dissolved in water Which have suflicient solubility are available. The principle here is the reduction of vapor pressure by a solute, as is Well understood by those skilled in the art. This will enable anyone skilled in the art to choose the solute best suited for their conditions. The above description is not to be taken as limiting, but descriptive of the best modes of employing the invention, which I claim to be:
1. A method of high vacuum steam distillation which comprises steam distilling oil under high vacuum, condensing the oil vapors, scrubbing the steam with a solvent, maintaining the temperature and concentration of the solvent mixture thus formed to maintain the mixture at a vapor pressure less than the vapor pressureof water at the temperature of the mixture and evaporating the water from the solvent mixture under a pressure, substantially that of the said steanrdistillation of the oil.
2. Method of steam distilling oil under high vacuum which comprises vaporizing oil with steam under high vacuum, condensing the oil vapors thus generated without condensing the steam, scrubbing said steam vapors witha solvent, maintaining the pressure of the solvent mixture below the vapor pressure of water at the temperature obtainable by use of available cooling water, evaporating the water from the solvent mixture under a pressure, substantially that of the said steam distillation of the oil.
3. Method of high vacuum steam distillation comprising distilling oil with steam under high vacuum, condensing the resulting oil vapors without condensing the. steam, scrubbing the steam with a solvent at a temperature not less thanthe available cooling water temperature and at an absolute pressure less than the vapor pressure of water at said cooling water temperature, removing the solvent water mixture, evaporating water from said solvent, re-introducing the regenerated steam into the, oil undergoing distillation, cooling said solvent by heat exchange with available cooling'water, and
cooling the steam to a temperature of itself insuflicient to condense the steam at the pressure maintained thereon by contacting said steam with a solvent and thus condensing the steam at the said pressure and temperature, removing the solvent water mixture, evaporating the water from the solvent, reintroducing the regenerated steam into the oil undergoing distillation, cooling the solvent and re-introducing the solvent into'the steam to be condensed, in cyclic operation.
5, A method of high vacuum steam distillation-Which comprises distilling oil at a low absolute pressure with steam, condensing the steam at a low absolute pressure by scrubbing the same with a liquid, evaporating the water from the mixture thus formed, re-introducing the evaporated water into the oil undergoing distillation and re-introducing the regenerated liquid to condense further steam in cyclic operation.
6. An apparatus for high vacuum distillation comprising a steam still, a condenser, means for maintaining high vacuumin the steam still and in the condenser, means for introducing a scrubbing liquid into the condenser, an evaporator, means for introducing the scrubbing liquid into the evaporator, means for introducing the regenerated steam from the evaporator into the steam still, means for withdrawing the scrubbing liquid from the evaporator, a cooler, means for passing the scrubbing liquid from the evaporator through the cooler and to the condenser.
Signed at Los Angeles, in the county of Los Angeles and State of California, this 29th day of F ebruary,'A. D. 1928.
EDWARD G. RAGATZ.
scrubbing further steam with saidsolvent in cyclic operation.
4. A method of high vacuum distillation of oil which comprises steam distilling oil at a low absolute pressure, fractionally condensing the oil but not condensing the steam,
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2723950A (en) * 1952-05-14 1955-11-15 Standard Oil Co Process for reduction of vapor losses in barometric condenser evacuations

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2723950A (en) * 1952-05-14 1955-11-15 Standard Oil Co Process for reduction of vapor losses in barometric condenser evacuations

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