US2472877A - Washing cellulose - Google Patents

Washing cellulose Download PDF

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US2472877A
US2472877A US542627A US54262744A US2472877A US 2472877 A US2472877 A US 2472877A US 542627 A US542627 A US 542627A US 54262744 A US54262744 A US 54262744A US 2472877 A US2472877 A US 2472877A
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water
cellulose
cations
washing
calcium
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US542627A
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Allquist John William
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Celanese Corp
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Celanese Corp
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    • DTEXTILES; PAPER
    • D01NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
    • D01FCHEMICAL FEATURES IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS; APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OF CARBON FILAMENTS
    • D01F2/00Monocomponent artificial filaments or the like of cellulose or cellulose derivatives; Manufacture thereof
    • D01F2/02Monocomponent artificial filaments or the like of cellulose or cellulose derivatives; Manufacture thereof from solutions of cellulose in acids, bases or salts
    • D01F2/04Monocomponent artificial filaments or the like of cellulose or cellulose derivatives; Manufacture thereof from solutions of cellulose in acids, bases or salts from cuprammonium solutions
    • DTEXTILES; PAPER
    • D01NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
    • D01FCHEMICAL FEATURES IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS; APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OF CARBON FILAMENTS
    • D01F11/00Chemical after-treatment of artificial filaments or the like during manufacture
    • D01F11/02Chemical after-treatment of artificial filaments or the like during manufacture of cellulose, cellulose derivatives, or proteins

Definitions

  • This invention concerns the washing and wet processing of yarns, fibers; fabrics and films which are essentially cellulosic in composition, such as cotton, linen, wood pulp and rayonhereinafter referred to as cellulosic fibers).
  • the yarn is generally washed with water containing dissolved salts of calcium, magnesium, sodium, etc.
  • These salts are found'in' natural waters and generally remain in such waters even after the more common processes?- of water purification.
  • the salt content in clear waters suitablefor industrial use' may runifrom the vicinity of 30 parts per. million to over 100 partsper million.
  • Calcium andmagnesium salts which, cause water to be hard may be removed bywrunning .the water through a commercialsoftener'which retains the calcium and magnesium and replaces it with a sodium salt,'.so that thetotal solids remaining in the water after passing through the softener are only slightly changed. 1
  • any cation from the salts which may be in the water may pick up, by chemical combination, any cation from the salts which may be in the water.
  • the ability of the cellulosic material to combine with or retain cations, particularly metallic cations depends upon pH; that at a pH of about 2.75 the metallic cations are entirely displaced from the carboxyl group and replaced by .a hydrogen ion, and the metallic cations meanwhile go into solution as salts in the surrounding aqueous medium. Further, I have found that at higher pH, more cations are retainer, and that thecarboxyl groups of the cellulose become completely saturated at pH 7 or higher. In this explanation I do not refer to the hydrogen ion of the acids, as a cation, although it is generally so considered-a I am referring more particularly to, the metallic cations.
  • the sodium could, of course, be washed out with distilled or demineralized water, if the cellulose were maintained in an acid condition before the distilled or demineralized water was applied.
  • the demineralized or distilled water wash must follow the acid wash directly.
  • a bit of aqua ammonia may be added to the distilled or demineralized water in the very last stages of washing, but in so doing, one must be reasonably certain that the undesired cations such as calcium, magnesium and sodium have al ready been washed out of the cellulose.
  • An amount of aqua ammonia suflicient to bring pH of the water to around 8 or 9 is generally satisfactory.
  • ammonium cation While the use of aqua ammonia brings about the combination of the ammonium cation and cellulose, the ammonium cation will not localize in the form of a salt deposit during subsequent drying as calcium, magnesium, or sodium does. The ammonium cation is largely lost during drying, being volatilized as ammonia.
  • soft waters water practically free of calcium and magnesium usually obtained by passin the hard waters through a zeolite softener, which retains the calcium and magnesium, exchanging them with sodium.
  • Waters equivalent to, or of the quality of, distilled water may be obtained from steam condensers, or by passing industrial waters through anion-cation exchangers, giving a final water, the solid content of which is generally well below 10 parts per million, none of which is calcium or magnesium and very little of which is cationic.
  • a suitable degree of acidity for loosenin such cations as calcium and magnesium is in the neighborhood of pH 2.5, although a pH varying from around 2 to 5 may be satisfactory for most purposes.
  • the wash water and desulfurizing material were made up with hard water, and that these liquids were drawn through the yarn by vacuum according to the conventional viscose rayon manufacturing procedure.
  • the cold water in this case would be at a temperature of about 0., hot water at about 65 C.
  • the desulfurizing solution is a solution of 0.35% to 0.40% ammonium sulfide at. a temperature of about C.
  • the bobbins were washed together until the 20 minutes wash had been completed.
  • the bobbins were then separated and the control continued washing as shown in the schedule.
  • the test bobbins having been washed thus far, were now given 110 minutes washing with hard water, acidified with hydrochloric acid-to pH 2, and then finished with minutes of demineralized water.
  • the ash of the test samples was largely silica, which is inert and harmless.
  • the dye affinity of the test yarn was noticeably greater than that of the control yarn as shown by the deeper shade of color of the yarn when dyed in the same dye bath with the control.
  • the salt spots can be reduced to an acceptable minimum in some cases by washing the yarn packages with a demineralized water at a pH of about 5. If the demineralizer is allowed to operate in such a way that the carbonic acid, normally found in the demineralized water, is allowed to remain dissolved in the water, the carbonic acid itself will yield a pH between 4 and 5 and effect a desirable reduction in retained cations. The excess carbonic acid is harmless since it is vaporized in subsequent drying operations.
  • the invention does not deal with the removal from cellulose of those salts which may have been a by-product or impurity from a spinning, dyeing, bleaching or other chemical treatment.
  • the invention relates only to the removal from the cellulose of salts in industrial waters, which the cellulose will adsorb or take up, to a certain extent, depending on pH, and which, under the usual conditions of washing with more or less neutral industrial waters, will stay in the cellulose to an extent where the ash content of an unpigmented, unweighted cellulose will be somewhere in the range of from 0.15% to 0.20% by weight.
  • Pigment for example, would not be affected; insoluble salts, such as lead sulfide, nickel sulfide and certain forms of iron oxide, would be affected to a small degree. But iron, nickel, lead, etc., as cations combined with the cellulose, would be dislodged by the treatment.
  • the water which comprises washing the cellulose with ordinary salt-bearing industrial water acidified with an inorganic acid to a pH- of from 2 to 5 to loosen and displace'said cations, and then washing out the displaced cations and'th'e acid with demineralize'd water.
  • the improved method of washing cellulosic 5 fibers to remove calcium, magnesium, sodium and other cations normally found in industrial Water and adsorbed or taken up by the cellulose from the water which comprises washing the cellulose with ordinary salt-bearing industrial water acidified with hydrochloric acid to a pH of from 2 to 5 to loosen and displace said cations, and then washing out the displaced cations and the acid with demineralized water.
  • the improved method of washing cellulosic fibers to remove calcium, magnesium, sodium and other cations normally found in industrial water and adsorbed or taken up by the cellulose from the water which comprises washing the cellulose with ordinary salt-bearing industrial water acidified with sulfuric acid to a pH of from 2 to 5 to loosen and displace said cations, and then washing out the displaced cations and the acid with demineralized water.

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  • Chemical & Material Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • General Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Textile Engineering (AREA)
  • Treatments For Attaching Organic Compounds To Fibrous Goods (AREA)

Description

Patented June 14, 1949 UNITED. STATES PATENT OFFICE v wAsniN iii uLosa I -mesne assignments, to Celanese Corporation of America, a corporation of Delaware No Drawing. Application June 28, 1944,
" Serial No. 542,627
This invention concerns the washing and wet processing of yarns, fibers; fabrics and films which are essentially cellulosic in composition, such as cotton, linen, wood pulp and rayonhereinafter referred to as cellulosic fibers).
Inthe wet processing-of cellulosic fibers, the yarn is generally washed with water containing dissolved salts of calcium, magnesium, sodium, etc. These salts are found'in' natural waters and generally remain in such waters even after the more common processes?- of water purification. The salt content in clear waters suitablefor industrial use'may runifrom the vicinity of 30 parts per. million to over 100 partsper million. Calcium andmagnesium salts which, cause water to be hard may be removed bywrunning .the water through a commercialsoftener'which retains the calcium and magnesium and replaces it with a sodium salt,'.so that thetotal solids remaining in the water after passing through the softener are only slightly changed. 1
'When cellulosic 'fibers are washed with ,salt
containing water, the" cellulose; retains a certain and definite amount ofuthe cations; the water, which remains with the fibers also contains a certain amount of dissolvedsalts. During the process of .drying yarn packages, such as are produced in the'manufacture of rayon, these salts creep to the outermost surfaces of the yarn package where the drying ismost rapid, and there the salts tend to localize or deposit, so that the final dried yarn package may show small spots or deposits scattered'over thepackage surface. s The localization of the salts, particularly under the infiuencerofheat, brings about a change in the cellulose at the point where the saltshave localized' which, in turn, is followed by a number of undesirable consequences in v the subsequent handlingof the yarn.- Dye-resist spots may be a result of the salt'deposits, In some cases the yarn is weakened so badly at the points where the salthas localized-that breaks follow in a subsequent processing.- -Sometimes the salt in creases the frictional properties of the thread at the spots described sothat the threads do not pass at uniform speeds through needles, guides and other textile devices, and jerky thread travel is obtained which may give rise to poor or defective stitch or weave. V a
It is now wellknown to" chemists familiar with cellulose that cellulose contains carboxyl groups andis slightly acid in nature. Another fact not quite as well realized is the property that cellu lose has, through its carboxyl groups, of combining with cations so: that-when cellulose is exs Claims. (01. 8:137)
posed to ordinary wash Waters it may pick up, by chemical combination, any cation from the salts which may be in the water. I have discovered that the ability of the cellulosic material to combine with or retain cations, particularly metallic cations, depends upon pH; that at a pH of about 2.75 the metallic cations are entirely displaced from the carboxyl group and replaced by .a hydrogen ion, and the metallic cations meanwhile go into solution as salts in the surrounding aqueous medium. Further, I have found that at higher pH, more cations are retainer, and that thecarboxyl groups of the cellulose become completely saturated at pH 7 or higher. In this explanation I do not refer to the hydrogen ion of the acids, as a cation, although it is generally so considered-a I am referring more particularly to, the metallic cations.
It has been proposed heretofore to remove from hydrolyzed cellulosic esters, salts of the alkaline earth metals by washing the cellulosic esters with acidified distilled water followed by repeated washings with distilledwater to remove the salt and acid. The washin of cellulosic material, such as rayon yarn and the like, with acidified distilled water to loosen calcium and magnesium and effect their removal from the yarn is prohibitively costly due to the high cost of distilling water.
-I have made the significant discovery that the calcium, magnesium and other cations combined with, or attached to, cellulosic fibers in the form of filaments, threads or fabrics may be displaced and removed by treatment with acidified hard or soft water (salt-bearing water) and that distilled water is not necessary in this operation. My invention, accordingly, provides an improved method of treating the cellulosic fibers with acidified salt-bearing hard or soft water to displace combined cations, followed by washing with distilled or demineralized water to remove the cations displaced by the acidified water.
In order to free the cellulose of calcium and magnesium as well as sodium and other cations, following exposure to hard waters, it is necessary to wash the yarn with water brought to a suitable pH with a little acid, such as sulfuric or hydrochloric acids, until the calcium or magnesium is loosened and freed and this, I have found, may be accomplished with ordinary industrial hard water orv with soft water. The cellulose may then be washed with distilled water or its equivalent until the calcium and magnesium salts are substantially removed. The cellulose, following acidification treatment, could be washed with soft water, and while the calcium and magnesium would be displaced from combination with the cellulose, they would be replaced with sodium. The sodium could, of course, be washed out with distilled or demineralized water, if the cellulose were maintained in an acid condition before the distilled or demineralized water was applied. To free the cellulose completely of cations (other than hydrogen) the demineralized or distilled water wash must follow the acid wash directly. To hasten the cellulose to neutrality in preparation for drying, a bit of aqua ammonia may be added to the distilled or demineralized water in the very last stages of washing, but in so doing, one must be reasonably certain that the undesired cations such as calcium, magnesium and sodium have al ready been washed out of the cellulose. An amount of aqua ammonia suflicient to bring pH of the water to around 8 or 9 is generally satisfactory. While the use of aqua ammonia brings about the combination of the ammonium cation and cellulose, the ammonium cation will not localize in the form of a salt deposit during subsequent drying as calcium, magnesium, or sodium does. The ammonium cation is largely lost during drying, being volatilized as ammonia.
By soft waters is meant water practically free of calcium and magnesium usually obtained by passin the hard waters through a zeolite softener, which retains the calcium and magnesium, exchanging them with sodium. Waters equivalent to, or of the quality of, distilled water may be obtained from steam condensers, or by passing industrial waters through anion-cation exchangers, giving a final water, the solid content of which is generally well below 10 parts per million, none of which is calcium or magnesium and very little of which is cationic.
A suitable degree of acidity for loosenin such cations as calcium and magnesium is in the neighborhood of pH 2.5, although a pH varying from around 2 to 5 may be satisfactory for most purposes. In the case of viscose yarns, for example, it is desirable to reduce the pH to a point which is around pH 2.75.
The following is an example of a washing operation carried out in accordance with the invention:
Bobbins of freshly spun viscose yarn, each having about 1 pound of yarn (bone dry) wound thereon, were taken directly after spinning and the regular wash necessary for such bobbins applied. Normally these particular bobbins woul have received washes such as follows:
Minutes Cold water 50 Hot water 50 Hot water 200 Desulfurizing solution 100 Hot water Hot water 60 Cold water 40 It will be understood that the wash water and desulfurizing material were made up with hard water, and that these liquids were drawn through the yarn by vacuum according to the conventional viscose rayon manufacturing procedure. The cold water in this case would be at a temperature of about 0., hot water at about 65 C. The desulfurizing solution is a solution of 0.35% to 0.40% ammonium sulfide at. a temperature of about C. The bobbins were washed together until the 20 minutes wash had been completed.
4 The bobbins were then separated and the control continued washing as shown in the schedule. The test bobbins, having been washed thus far, were now given 110 minutes washing with hard water, acidified with hydrochloric acid-to pH 2, and then finished with minutes of demineralized water.
After drying, the yarns compared as follows in ash content:
Per cent Control 0.17 Test 0.025
The ash of the test samples was largely silica, which is inert and harmless.
The dye affinity of the test yarn was noticeably greater than that of the control yarn as shown by the deeper shade of color of the yarn when dyed in the same dye bath with the control.
In the removal of calcium, magnesium, sodium and other cations from yarn, with the object of preventing the localization of their salts on parts of yarn packages during drying, it has been found that in some cases it is not necessary to remove all the undesirable cationic material to prevent localization of salt spots. The salt spots can be reduced to an acceptable minimum in some cases by washing the yarn packages with a demineralized water at a pH of about 5. If the demineralizer is allowed to operate in such a way that the carbonic acid, normally found in the demineralized water, is allowed to remain dissolved in the water, the carbonic acid itself will yield a pH between 4 and 5 and effect a desirable reduction in retained cations. The excess carbonic acid is harmless since it is vaporized in subsequent drying operations. While at the higher range of pH, the removal of cations is not complete, if the washing is prolonged enough, I have found that the ash content can be lowered from the range of from 0.15% to 0.20% to the range of from 0.07% to 0.08%. As I have said, this is satisfactory for certain purposes, but in order to obtain complete removal, a lower pH must be used.
The invention does not deal with the removal from cellulose of those salts which may have been a by-product or impurity from a spinning, dyeing, bleaching or other chemical treatment. The invention relates only to the removal from the cellulose of salts in industrial waters, which the cellulose will adsorb or take up, to a certain extent, depending on pH, and which, under the usual conditions of washing with more or less neutral industrial waters, will stay in the cellulose to an extent where the ash content of an unpigmented, unweighted cellulose will be somewhere in the range of from 0.15% to 0.20% by weight. Pigment, for example, would not be affected; insoluble salts, such as lead sulfide, nickel sulfide and certain forms of iron oxide, would be affected to a small degree. But iron, nickel, lead, etc., as cations combined with the cellulose, would be dislodged by the treatment.
I claim:
1. The improved method of washing cellulosic fibers to remove calcium, magnesium, sodium and other cations normally found in industrial water and adsorbed or taken up by the cellulose from. the water which comprises washing the cellulose with ordinary salt-bearing industrial water acidified with an inorganic acid to a pH- of from 2 to 5 to loosen and displace'said cations, and then washing out the displaced cations and'th'e acid with demineralize'd water.
2. The improved method of washing cellulosic 5 fibers to remove calcium, magnesium, sodium and other cations normally found in industrial Water and adsorbed or taken up by the cellulose from the water which comprises washing the cellulose with ordinary salt-bearing industrial water acidified with hydrochloric acid to a pH of from 2 to 5 to loosen and displace said cations, and then washing out the displaced cations and the acid with demineralized water.
3. The improved method of washing cellulosic fibers to remove calcium, magnesium, sodium and other cations normally found in industrial water and adsorbed or taken up by the cellulose from the water which comprises washing the cellulose with ordinary salt-bearing industrial water acidified with sulfuric acid to a pH of from 2 to 5 to loosen and displace said cations, and then washing out the displaced cations and the acid with demineralized water.
JOHN WILLIAM AILQUIST.
REFERENCES CITED The following references are of record in the file of this patent:
UNITED STATES PATENTS Number Name Date 1,802,935 Banigan Apr. 28, 1931 2,316,379 Wolter Apr. 13, 1943 OTHER REFERENCES
US542627A 1944-06-28 1944-06-28 Washing cellulose Expired - Lifetime US2472877A (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2922728A (en) * 1956-11-05 1960-01-26 American Enka Corp Prevention of yellowing in freshly spun viscose rayon with tartaric, citric or gluconic acid
US3419345A (en) * 1961-10-27 1968-12-31 Du Pont Neutralization of hydrophilic gel fibers of a cellulose derivative
US4383962A (en) * 1979-09-27 1983-05-17 Asahi Kasei Kogyo Kabushiki Kaisha Process for producing viscose rayon filament yarn

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1802935A (en) * 1929-05-22 1931-04-28 Du Pont Rayon Co Method of washing artificial silk
US2316379A (en) * 1938-06-28 1943-04-13 Procter & Gamble Process of removing impurities from washed textiles

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1802935A (en) * 1929-05-22 1931-04-28 Du Pont Rayon Co Method of washing artificial silk
US2316379A (en) * 1938-06-28 1943-04-13 Procter & Gamble Process of removing impurities from washed textiles

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2922728A (en) * 1956-11-05 1960-01-26 American Enka Corp Prevention of yellowing in freshly spun viscose rayon with tartaric, citric or gluconic acid
US3419345A (en) * 1961-10-27 1968-12-31 Du Pont Neutralization of hydrophilic gel fibers of a cellulose derivative
US4383962A (en) * 1979-09-27 1983-05-17 Asahi Kasei Kogyo Kabushiki Kaisha Process for producing viscose rayon filament yarn

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