US2804172A - Soap deaeration - Google Patents

Soap deaeration Download PDF

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Publication number
US2804172A
US2804172A US236038A US23603851A US2804172A US 2804172 A US2804172 A US 2804172A US 236038 A US236038 A US 236038A US 23603851 A US23603851 A US 23603851A US 2804172 A US2804172 A US 2804172A
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soap
chamber
steam
deaerating
molten
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US236038A
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Sender Leopold
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Sharples Corp
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Sharples Corp
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    • CCHEMISTRY; METALLURGY
    • C11ANIMAL OR VEGETABLE OILS, FATS, FATTY SUBSTANCES OR WAXES; FATTY ACIDS THEREFROM; DETERGENTS; CANDLES
    • C11DDETERGENT COMPOSITIONS; USE OF SINGLE SUBSTANCES AS DETERGENTS; SOAP OR SOAP-MAKING; RESIN SOAPS; RECOVERY OF GLYCEROL
    • C11D13/00Making of soap or soap solutions in general; Apparatus therefor
    • C11D13/02Boiling soap; Refining

Definitions

  • the present invention relates to a method and apparatus for deaerating molten soap.
  • a method for the continuous product-ion of soap is described in U. S. Patent 2,300,749, wherein a fat is mixed with a saponifying reagent for a time, a graining agent is added, and the resulting soap containing mixture is passed to a centrifugal rotor and there subjected to contrifugation to separate the aqueous phase resulting from said mixing and graining operation from the soap-containing mass resulting from said operation.
  • the object of the present invention is to provide an improved apparatus and method whereby the discharging soap mass containing air may be deaerated or freed from such air.
  • Figure 1 is a schematic view of one form of apparatus for deaerating neat soap
  • Figure 2 is a schematic view of apparatus for deaerating neat soap.
  • molten aerated neat soap is supplied at a suitable rate from a reservoir by pump 11 through conduit 12 to a nozzle 14 extending within an elongated deaerating chamber 15.
  • Chamber 15, for example, may be formed of a tubular steel cylinder 8 feet long and 6 inches in diameter.
  • Nozzle 14 feeds molten soap to the interior of chamber 15 a modified form of brief period ofso as to provide a relatively thin molten soap film 35 on the lower interior surface of chamber 15 which flows continually toward the outlet 25.
  • Chamber 15 is inclined at a suitable angle, as for example 30 from the horizontal, to permit a predetermined period of dwell or travel time of the liquid soap film in the chamber 15.
  • the chamber 15 is provided with a suitable surrounding steamheated jacket 17 connected to a source of steam supply 18 and provided with a condensate trap 19 whereby the temperature to which the chamber 15 is heated can be controlled for maintaining the soap therein in molten flowable condition.
  • the lower end of chamber 15 is provided with an outlet 25 extending flush with the inner surface of the chamber. Outlet 25 is connected to a conduit 26 and a wet vacuum pump 27 which serves to convey the deaerated soap to reservoir 29 through conduit 28. Vacuum pump 27 also provides a reduced pressure within chamber 15, for example, from 9 to 15 in. Hg.
  • a gauge 21 indicates the vacuum existing in the chamber 15.
  • Live steam is supplied at the inlet end of chamber 15 by a supply line 30 controlled by a regulator valve 31 which is actuated by a controller 2!). Controller 20 is connected to chamber 15 by line 24 so that it is responsive to the amount of live steam supplied by line 23 to chamber 15. The amount of live steam supplied by line 23 to chamber 15 can thus be controlled by the variation of pressure in chamber 15.
  • An alternative control for the steam supply can be obtained by providing a tempera ture responsive element 38 in soap reservoir 29 which is connected by suitable means .39 to control valve 31 in steam line 30.
  • neat soap stock for example, having a specific gravity 0.947 and 62.8% by weight of total fatty acid was continuously fed at a temperature of 201 F. through nozzle 14 to chamber 15 so as to form a relatively thin layer or film 35 of molten soap.
  • the chamber 15 was maintained under reduced atmospheric pressure at about 13 in. Hg and dry live steam was continuously fed by line 23 into chamber 15.
  • the vacuum and live steam in chamber 15 served to deaerate the soap, the steam serving to sweep the free air from the chamber.
  • the temperature of the jacket 17 was maintained at about 220 F.
  • the completely deaerated neat soap stock fed to reservoir 29 had a specific gravity of 1.030 and 62.8% by weight total fatty acid.
  • Another illustrative run was made by feeding molten neat soap stock to chamber 15 at a temperature of 194 F.
  • the initial soap stock had a specific gravity of 0.925 and a total fatty acid content of 64.2% by weight.
  • a vacuum of 10 in. Hg was maintained in chamber 15 during the run while live steam was admitted to chamber 15 by line 23 at a rate so that the soap issuing through outlet 25 was completely deaerated and had a specific gravity of 1.028 and total fatty acid content of 64.2% by weight.
  • Molten soap may be fed through the apparatus illustrated at about 1000 to about 2500 pounds per hour at a vacuum ranging from 2 or 3 in. Hg to about 25 in. Hg for completely deaerating the molten soap.
  • FIG. 2 illustrates a modified apparatus for deaerating molten liquid neat soap stock which is supplied from reservoir 40 through conduit 41 by pump 42 and through conduit 43 to nozzle 44 extending within tank 45.
  • the tank is connected to a vacuum ejector or vacuum pump 48.
  • a gauge 47 indicates the vacuum in tank 45.
  • Live steam is supplied to tank 45 by line 49.
  • the molten soap is sprayed through nozzle 44 in tank 45 and is also subjected to a stream of live steam from line 49.
  • the deaerated soap stock forms a pool 50 in the bottom of tank 45 and is withdrawn through conduit 51, pump 52 and conduit 53 to a deaerated soap reservoir 54.
  • the present invention provides a very efficient continuous means for deaerating neat soap stock which otherwise cannot be directly processed into satisfactory finished cakes or bars using conventional soap plant equipment and methods.
  • the molten soap is spread into a relatively thin film and is continuously fed through a deaerating zone which 1s maintained under controlled reduced atmospheric pressure While live steam is admitted to the zone to purge or sweep free air liberated from the aerated soap.
  • the pressure in the deaerating zone may be maintained advantageously for example at about 9 to about in. Hg or, i
  • the molten soap flows con-- tinuously through a deaerating zone which is subjected to vacuum to reduce the atmospheric pressure in the zone and live steam is simultaneously admitted to the zone to sweep free air out of the zone.
  • the soap may be sprayed in a chamber provided witha steam atmosphere to deaerate the soap.
  • the water content of the soap may be increased or decreased simultaneously with the deaeration by varying the pressure maintained in the deaerating zone and/or varying the temperature of the soap mass, In general it is preferred to have the moisture content of the deaerated soap at about the same amount as in the aerated soap.
  • the moisture content of the deaerated soap may thus be controlled by adjusting the pressure in the deaerating zone or by maintaining the temperature of the aerated soap leaving the deaerating zone at the same temperature of the aerated soap fed to the deaerating zone.
  • Any molten aerated soap may be processed in accordance with my invention to produce a non-aerated neat soap for making bar soap having smooth polished surfaces and desirable plasticity so that the bar can be slightly twisted or deformed during use without rupturing as contrasted with soap bars made from aerated soap stock which have a poor surface appearance due to air bubbles and lack of suitable plasticity.
  • Attenuated form or its equivalent, is used to mean a film, spray, or other thin or fine form.
  • a process for deaerating soap having air entrained therein as a discontinuous phase which comprises subjecting said soap in molten condition and in attenuated form to reduced pressure in an enclosure to liberate air therefrom, introducing steam into and passing said steam through said enclosure in contact with the surface only of said soap for sweeping air liberated from said soap from said enclosure, and regulating the temperature of said soap and the pressure within said enclosure to control the water content of said soap.
  • a process for deaerating soap having air entrained therein as a discontinuous phase which comprises flowing said soap in molten condition through a chamber, subjecting said soap in attenuated form to reduced pressure while in said chamber to liberate air therefrom, introducing steam into and passing said steam through said chamber and into contact with the surface only of said soap for sweeping air liberated from saidsoap from said chamber, and regulating the temperature of sad soap and the pressure within said chamber to control the water content of said soap.
  • a process for deaerating soap having air entrained therein as a discontinuous phase which comprises separately introducing into and flowing through a chamber a continuous stream of said soap in molten condition and a continuous stream of steam while maintaining a vacuum Within said chamber of between2 and 25 inches Hg, attenuating said soap while in said chamber to liberate air therefrom, contacting the surface only of said soap with said steam to displace from the surface of said soap the air thusliberated, and regulating the temperature of said soap and the pressure within said chamber to control the water content of said soap.

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  • Chemical & Material Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Oil, Petroleum & Natural Gas (AREA)
  • Wood Science & Technology (AREA)
  • Organic Chemistry (AREA)
  • Detergent Compositions (AREA)

Description

Filed July 10. 1951 2 Sheets-Sheet l INVENTOR. LEOROLD SENDER BY F-Uww ATTORNEY Aug. 27, 1957 L. SENDER SOAP DEAERATION 2 Sheets-Sheet 2 Filed July 10, 1951 mm E EDPFW 1 W Qu aoom v28 2 INVENTOR. LEOPOLD SENDER B H 6 G M ATTORNEY nited States Patent SOAP DEAERATION Philadelphia, Pa., assignor to The Leopold Sender,
a corporation of Delaware The present invention relates to a method and apparatus for deaerating molten soap.
A method for the continuous product-ion of soap is described in U. S. Patent 2,300,749, wherein a fat is mixed with a saponifying reagent for a time, a graining agent is added, and the resulting soap containing mixture is passed to a centrifugal rotor and there subjected to contrifugation to separate the aqueous phase resulting from said mixing and graining operation from the soap-containing mass resulting from said operation. In such a process, there may be more than one stage for the addition of alkali followed by centrifugation, with the final centrifugal separation resulting in a continuous and separate discharge of the aqueous phase such as nigre or pitch-water on the one part and neat soap on the other part.
One type of centrifuge that may be used for this separation is illustrated in U. S. Patent 1,634,243, wherein the separated substances are discharged over weirs in the centrifuge bowl, and these discharges are'separately collected in covers. In order to develop centrifugal force adequate for the separation, these rotors turn at a high R. P. M., and have a high peripheral speed. The result is that the substances overflowing the outlets discharge in the form of fine dispersed particles. These particles strike the Walls of the covers surrounding the centrifuge bowl and are there collected and flow away through the spouts. A considerable amount of air is entrained as a discontinuous phase when the particles strike the walls of the covers, and air thus incorporated in a soap mass separates very slowly, and some remains dispersed in the soap, affecting its texture. One method of overcoming this difliculty is to continuously flow steam into the covers to displace the air. The steam vapor entrained in the soap condenses, so that there is no dispersedvapor in the soap mass as it discharges. This is efiective, however, only when the discharging soap has a water vapor pressure close to atmospheric, for, if it is colder, the quick condensation of the steam makes it diflicult to maintain the space in the covers free from air.
The object of the present invention is to provide an improved apparatus and method whereby the discharging soap mass containing air may be deaerated or freed from such air.
Details and advantages of the present invention will be apparent from the following specification and accompanying drawings, wherein Figure 1 is a schematic view of one form of apparatus for deaerating neat soap, and
Figure 2 is a schematic view of apparatus for deaerating neat soap.
Referring to Figure la continuous stream of molten aerated neat soap is supplied at a suitable rate from a reservoir by pump 11 through conduit 12 to a nozzle 14 extending within an elongated deaerating chamber 15. Chamber 15, for example, may be formed of a tubular steel cylinder 8 feet long and 6 inches in diameter. Nozzle 14 feeds molten soap to the interior of chamber 15 a modified form of brief period ofso as to provide a relatively thin molten soap film 35 on the lower interior surface of chamber 15 which flows continually toward the outlet 25. Chamber 15 is inclined at a suitable angle, as for example 30 from the horizontal, to permit a predetermined period of dwell or travel time of the liquid soap film in the chamber 15. The chamber 15 is provided with a suitable surrounding steamheated jacket 17 connected to a source of steam supply 18 and provided with a condensate trap 19 whereby the temperature to which the chamber 15 is heated can be controlled for maintaining the soap therein in molten flowable condition. The lower end of chamber 15 is provided with an outlet 25 extending flush with the inner surface of the chamber. Outlet 25 is connected to a conduit 26 and a wet vacuum pump 27 which serves to convey the deaerated soap to reservoir 29 through conduit 28. Vacuum pump 27 also provides a reduced pressure within chamber 15, for example, from 9 to 15 in. Hg. A gauge 21 indicates the vacuum existing in the chamber 15. Live steam is supplied at the inlet end of chamber 15 by a supply line 30 controlled by a regulator valve 31 which is actuated by a controller 2!). Controller 20 is connected to chamber 15 by line 24 so that it is responsive to the amount of live steam supplied by line 23 to chamber 15. The amount of live steam supplied by line 23 to chamber 15 can thus be controlled by the variation of pressure in chamber 15. An alternative control for the steam supply can be obtained by providing a tempera ture responsive element 38 in soap reservoir 29 which is connected by suitable means .39 to control valve 31 in steam line 30.
In carrying out my process neat soap stock, for example, having a specific gravity 0.947 and 62.8% by weight of total fatty acid was continuously fed at a temperature of 201 F. through nozzle 14 to chamber 15 so as to form a relatively thin layer or film 35 of molten soap. The chamber 15 was maintained under reduced atmospheric pressure at about 13 in. Hg and dry live steam was continuously fed by line 23 into chamber 15. The vacuum and live steam in chamber 15 served to deaerate the soap, the steam serving to sweep the free air from the chamber. The temperature of the jacket 17 was maintained at about 220 F. The completely deaerated neat soap stock fed to reservoir 29 had a specific gravity of 1.030 and 62.8% by weight total fatty acid.
Another illustrative run was made by feeding molten neat soap stock to chamber 15 at a temperature of 194 F. The initial soap stock had a specific gravity of 0.925 and a total fatty acid content of 64.2% by weight. A vacuum of 10 in. Hg was maintained in chamber 15 during the run while live steam was admitted to chamber 15 by line 23 at a rate so that the soap issuing through outlet 25 was completely deaerated and had a specific gravity of 1.028 and total fatty acid content of 64.2% by weight. Molten soap may be fed through the apparatus illustrated at about 1000 to about 2500 pounds per hour at a vacuum ranging from 2 or 3 in. Hg to about 25 in. Hg for completely deaerating the molten soap.
Figure 2 illustrates a modified apparatus for deaerating molten liquid neat soap stock which is supplied from reservoir 40 through conduit 41 by pump 42 and through conduit 43 to nozzle 44 extending within tank 45. The tank is connected to a vacuum ejector or vacuum pump 48. A gauge 47 indicates the vacuum in tank 45. Live steam is supplied to tank 45 by line 49. The molten soap is sprayed through nozzle 44 in tank 45 and is also subjected to a stream of live steam from line 49. The deaerated soap stock forms a pool 50 in the bottom of tank 45 and is withdrawn through conduit 51, pump 52 and conduit 53 to a deaerated soap reservoir 54.
The present invention provides a very efficient continuous means for deaerating neat soap stock which otherwise cannot be directly processed into satisfactory finished cakes or bars using conventional soap plant equipment and methods. In accordance with my invention the molten soap is spread into a relatively thin film and is continuously fed through a deaerating zone which 1s maintained under controlled reduced atmospheric pressure While live steam is admitted to the zone to purge or sweep free air liberated from the aerated soap. The pressure in the deaerating zone may be maintained advantageously for example at about 9 to about in. Hg or, i
and live steam in a deaerating zone to deaerate' the soap.e As illustrated in Figure 1, the molten soap flows con-- tinuously through a deaerating zone which is subjected to vacuum to reduce the atmospheric pressure in the zone and live steam is simultaneously admitted to the zone to sweep free air out of the zone. As shown in Figure 2, the soap may be sprayed in a chamber provided witha steam atmosphere to deaerate the soap. The water content of the soap may be increased or decreased simultaneously with the deaeration by varying the pressure maintained in the deaerating zone and/or varying the temperature of the soap mass, In general it is preferred to have the moisture content of the deaerated soap at about the same amount as in the aerated soap. The moisture content of the deaerated soap may thus be controlled by adjusting the pressure in the deaerating zone or by maintaining the temperature of the aerated soap leaving the deaerating zone at the same temperature of the aerated soap fed to the deaerating zone.
Any molten aerated soap may be processed in accordance with my invention to produce a non-aerated neat soap for making bar soap having smooth polished surfaces and desirable plasticity so that the bar can be slightly twisted or deformed during use without rupturing as contrasted with soap bars made from aerated soap stock which have a poor surface appearance due to air bubbles and lack of suitable plasticity.
For convenience in the claims the term attenuated form, or its equivalent, is used to mean a film, spray, or other thin or fine form.
It is to be understood that details of the process and apparatus'herein described may be varied by those skilled in the art and such modifications and variations are intended to be included within the'scope of the appended claims.
I claim:
1. A process for deaerating soap having air entrained therein as a discontinuous phase which comprises subjecting said soap in molten condition and in attenuated form to reduced pressure in an enclosure to liberate air therefrom, introducing steam into and passing said steam through said enclosure in contact with the surface only of said soap for sweeping air liberated from said soap from said enclosure, and regulating the temperature of said soap and the pressure within said enclosure to control the water content of said soap.
2. A process for deaerating soap having air entrained therein as a discontinuous phase which comprises flowing said soap in molten condition through a chamber, subjecting said soap in attenuated form to reduced pressure while in said chamber to liberate air therefrom, introducing steam into and passing said steam through said chamber and into contact with the surface only of said soap for sweeping air liberated from saidsoap from said chamber, and regulating the temperature of sad soap and the pressure within said chamber to control the water content of said soap.
3. A process for deaerating soap having air entrained therein as a discontinuous phase which comprises separately introducing into and flowing through a chamber a continuous stream of said soap in molten condition and a continuous stream of steam while maintaining a vacuum Within said chamber of between2 and 25 inches Hg, attenuating said soap while in said chamber to liberate air therefrom, contacting the surface only of said soap with said steam to displace from the surface of said soap the air thusliberated, and regulating the temperature of said soap and the pressure within said chamber to control the water content of said soap.
4. The process of claim 3 wherein the vacuum within the chamber is maintained between 2 and 15 inches Hg.
5. The process of claim 4 wherein the vacuum within the chamber is maintained between 9 and 15 inches Hg.
the water in the soap while 6. The process of claim 3 wherein the pressure within the chamber is maintained close to the vapor pressure of in the chamber.
7. The process of claim 3 wherein the soap is attenuated into film form.
' 8. The process of claim 3 wherein the soap is attenuated into spray form. t
' References Cited in the file of this patent UNITED STATES PATENTS
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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3071913A (en) * 1958-10-30 1963-01-08 Blevitzky Robert Apparatus for treating boiler water
US3183645A (en) * 1961-11-10 1965-05-18 Mass Transfer Inc Process for deodorization of an odiferous atmosphere
US3230691A (en) * 1962-03-15 1966-01-25 Kurashiki Rayon Co Method for continuously defoaming concentrated aqueous solutions of polyvinyl alcohol
US4032497A (en) * 1974-07-19 1977-06-28 Kureha Kagaku Kogyo Kabushiki Kaisha Method and apparatus for removal of unreacted monomer from synthesized high polymer latex
US4500329A (en) * 1983-04-25 1985-02-19 United States Of America As Represented By Secretary Of The Interior Self-actuating vacuum gas/liquid separator

Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US558970A (en) * 1896-04-28 jackson
US2041059A (en) * 1932-09-30 1936-05-19 Aluminium Plant & Vessel Co Method of and apparatus for removing gases from milk or cream or other liquids
US2204062A (en) * 1937-07-10 1940-06-11 Permutit Co Water deaerator and purifier
US2252313A (en) * 1939-03-31 1941-08-12 Raymond N Bostock Deaerator for carbonating systems
US2283456A (en) * 1939-08-23 1942-05-19 Firm Noblee & Thorl G M B H Process for separating unsaponifiable substances from their mixtures or compounds with saponifiable substances
US2343317A (en) * 1941-04-04 1944-03-07 Taylor Instrument Co Apparatus for governing deaeration
US2355057A (en) * 1941-07-18 1944-08-08 Du Pont Apparatus for deaerating viscose compositions
US2408021A (en) * 1944-01-17 1946-09-24 Aluminium Plant & Vessel Co Treatment of liquids
US2420356A (en) * 1942-08-29 1947-05-13 Colgate Palmolive Peet Co Degasification
US2634907A (en) * 1950-06-24 1953-04-14 Sharples Corp Process and apparatus for centrifugal deaeration

Patent Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US558970A (en) * 1896-04-28 jackson
US2041059A (en) * 1932-09-30 1936-05-19 Aluminium Plant & Vessel Co Method of and apparatus for removing gases from milk or cream or other liquids
US2204062A (en) * 1937-07-10 1940-06-11 Permutit Co Water deaerator and purifier
US2252313A (en) * 1939-03-31 1941-08-12 Raymond N Bostock Deaerator for carbonating systems
US2283456A (en) * 1939-08-23 1942-05-19 Firm Noblee & Thorl G M B H Process for separating unsaponifiable substances from their mixtures or compounds with saponifiable substances
US2343317A (en) * 1941-04-04 1944-03-07 Taylor Instrument Co Apparatus for governing deaeration
US2355057A (en) * 1941-07-18 1944-08-08 Du Pont Apparatus for deaerating viscose compositions
US2420356A (en) * 1942-08-29 1947-05-13 Colgate Palmolive Peet Co Degasification
US2408021A (en) * 1944-01-17 1946-09-24 Aluminium Plant & Vessel Co Treatment of liquids
US2634907A (en) * 1950-06-24 1953-04-14 Sharples Corp Process and apparatus for centrifugal deaeration

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3071913A (en) * 1958-10-30 1963-01-08 Blevitzky Robert Apparatus for treating boiler water
US3183645A (en) * 1961-11-10 1965-05-18 Mass Transfer Inc Process for deodorization of an odiferous atmosphere
US3230691A (en) * 1962-03-15 1966-01-25 Kurashiki Rayon Co Method for continuously defoaming concentrated aqueous solutions of polyvinyl alcohol
US4032497A (en) * 1974-07-19 1977-06-28 Kureha Kagaku Kogyo Kabushiki Kaisha Method and apparatus for removal of unreacted monomer from synthesized high polymer latex
US4500329A (en) * 1983-04-25 1985-02-19 United States Of America As Represented By Secretary Of The Interior Self-actuating vacuum gas/liquid separator

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