US2959514A - Dry strength paper - Google Patents

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US2959514A
US2959514A US715488A US71548858A US2959514A US 2959514 A US2959514 A US 2959514A US 715488 A US715488 A US 715488A US 71548858 A US71548858 A US 71548858A US 2959514 A US2959514 A US 2959514A
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polymer
fibers
dry
paper
linkages
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Norman T Woodberry
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Wyeth Holdings LLC
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American Cyanamid Co
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Priority to FR786750A priority patent/FR1225728A/en
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    • DTEXTILES; PAPER
    • D21PAPER-MAKING; PRODUCTION OF CELLULOSE
    • D21HPULP COMPOSITIONS; PREPARATION THEREOF NOT COVERED BY SUBCLASSES D21C OR D21D; IMPREGNATING OR COATING OF PAPER; TREATMENT OF FINISHED PAPER NOT COVERED BY CLASS B31 OR SUBCLASS D21G; PAPER NOT OTHERWISE PROVIDED FOR
    • D21H17/00Non-fibrous material added to the pulp, characterised by its constitution; Paper-impregnating material characterised by its constitution
    • D21H17/20Macromolecular organic compounds
    • D21H17/33Synthetic macromolecular compounds
    • D21H17/34Synthetic macromolecular compounds obtained by reactions only involving carbon-to-carbon unsaturated bonds

Definitions

  • paper composed of a waterlaid web of cellulosic papermaking fibers bonded together by a small adsorbed amount of a normally water-soluble linear carbon chain polymer con- .taining carbamyl and hydroxyamidino side groups (as more particularly hereinafter described) possesses substantially improved dry strength and yet possesses low wet strength.
  • the dry tensile strength of paper of the present invention is improved by about 50%75% as a result of the strengthening action of the polymer, and dry burst values are improved by upward of 75%85%.
  • the paper '(at ordinary book paper weight) possesses a wet tensile strength of less than about 3 lbs./in., which means that it can be repulped in ordinary papermill equipment.
  • the polyacrylamidoxime polymer of the present invention is soluble in water yet is substantively adsorbed therefrom by cellulose fibers. Accordingly, paper of the present invention is manufactured by forming an aqueous suspension of papermaking cellulosic fibers, adding thereto a small amount of an aqueous solution of polyacrylamidoxime polymer, sheeting the fibers to form a cellulosic web, and heating the web until dry.
  • the polymers of the present invention are non-thermosetting and thus do not require heat for development of their strengthening properties. However, they are thermostable and thus the wet webs may be dried without harm on steam-heated rolls in the customary temperature range of 190 F. to 250 F.
  • the polymer is well adsorbed by fibers which have been rosin sized, and the beneficial effect of the polymer in increasing the dry strength is not significantly v diminished by the presence of such sizing on the fibers.
  • vention is ampholytic, and thus may be applied as an anionic or cationic material. It is insensitive to pH and affords substantially the same results at pH 6.5 as at pH 3.5. The evidence is that somewhat better dry strength is developed when the pH of the suspension during addition of the polymer is between 4.5 and 6.5, and this range accordingly is preferred.
  • Best dry strength values are usually obtained when the fibrous suspension during addition of the polymer contains alum. Since the polymer is self-substantive the alum does not appear to act as mordant or precipitant. Evidently the paper produced from suspensions containing alum carries the polymer in the form of an alum complex. About of dissolved alum in the suspension (based on the dry weight of cellulose fibers) is sufiicient to cause a substantial increase in the dry strength imparted by the resin, and more than about 2% appears to be unnecessary for the purpose. An intermediate amount in the range of /;%-1%% is accordingly preferred, it being understood that much larger amounts may be present without harm. With or without alum, adsorption of the polymer by the fibers is substantially complete.
  • the polymer employed in the present invention consists predominantly of hydroxyamidinoethylene and carbamylethylene linkages,"the theoretical formulaelof which are NH CHzCH(CNHOH)-- and 0 CH CH(CNHa)'
  • the former linkage may exist in the tautomeric form and moreover two adjacent hydroxyamidino substituents may react or coordinate to form ,a linkage of the type to.
  • HON g NOH Paper containing polymers having such linkages is within the scope of the invention.
  • polymers containing additional groups which act as diluents, or spacers, or which act in known manner for other purposes may carry in minor, proportion alkyl or aryl, alkoxy, hydroxyl, carboxyl, ester, amine, carboxy, quaternary ammonium, and nitrile groups as supplemental substituents. Up to 50 mol percent of such substituents may be present, it being understood that in the case of the hydrophobic substituents the amounts thereof should be limited so that the polymer remains water-soluble to the extent of at least 5%.
  • the hydroxyamidino and carbamyl groups of the polymer are active ionically and evidently serve two principal functions.
  • the first is to provide electrostatic loci, capable of acting ionically by which the polymer macromolecule as a whole is attracted to and substantively adsorbed by cellulose fibers in aqueous suspension in the presence or absence of dissolved polyvalent metal salts.
  • the second function is to provide dry 3 strength.
  • the hydroxyamidino grouping is effective electrostatically in very small amounts and as little as 1% based on the remaining substituents present has been sufiicient to render the macromolecule cationically active and self-substantive to cellulose.
  • Considerable improvement in the dry strength is obtained by use of polymers containing a larger proportion of these groupings, particularly when the polymer contains hydroxyamidinoethylene and carbamylethylene linkages in ratio between about 1:10 and 3:10.
  • Increasing the proportion of hydroxyamidino groups in the macromolecule results in further improvement in dry strength. This improvement, however, becomes progressively less as the proportion rises above this ratio range and accordingly the range stated is regarded as the practical maximum.
  • the carbamylethylene linkages which constitute the other major functional grouping in the polymer are ionically inert, but powerfully coordinate or react with the cellulose to provide dry strength. Apparently for the latter purpose they are somewhat more effective than the hydroxyamidinoethylene linkages, and accordingly, the number of carbamylethylene linkages should be at least of the number of hydroxyamidinoethylene linkages.
  • the polymers employed in the present invention may be prepared in any convenient manner. In practice they are most conveniently prepared by copolymerizing a watersoluble vinyl nitrile and a water-soluble vinyl amide in major proportion with or without supplementary or di1uent vinyl material to form an essentially linear carbon chain amide-nitrile polymer.
  • nitrile groups are then reacted with hydroxylamine to form hydroxyamidino groups in the proportion specified. It is preferred to form the polymer by copolymerizing acrylonitrile (methacrylonitrile, crotononitrile, etc.) with acrylamide or similar amide having an unsubstituted -NH amide substituent in molar ratio between about 70:30 and 90:10 and then heating with hydroxylamine to convert nitrile groups to hydroxyamidino groups in proportion specified above.
  • acrylonitrile methacrylonitrile, crotononitrile, etc.
  • the polymer may be subjected to other reactions before or after the hydroxylamine reaction, and thus any ester groups present may be subjected to hydrolysis to form hydroxy or acid groups; any nitro groups present may be reduced to amine groups; any chloro groups may be reacted with tertiary amines to form quaternary ammonium groups.
  • the vinyl polymerization leading to formation of the linear chain polymer may be performed in aqueous medium using a redox catalyst, and molecular growth to an advanced stage should be favored.
  • the development of increased dry strength requires the use of polymers having a molecular weight in excess of about 100,000 (as determined by the Staudinger method based on viscosity) and considerably better results are obtained when the molecular weight is upwards of 500,000, which is the preferred lower limit.
  • the polymers are too viscous for commercial use at molecular weights in excess of 5,000,000 and this therefore is the maximum of the preferred range.
  • Example 1 The following illustrates the manufacture of paper of excellent dry tensile strength but low wet strength according to the present invention by use of a preferred hydroxyamidinoethylene-carbamylethylene polymer.
  • the resin was prepared by dissolving 5.0 gm. of an 80%20% (molar ratio) acrylamidezacrylonitrile polymer (molecular weight 500,000) in 200 ml. of water, adding 0.655 gm. of hydroxylamine hydrochloride (equivalent to 64% of the nitrile groups present), adjusting the pH to 6.8 with dilute aqueous NaOH solution, and heating the mixture for 30 minutes at C.
  • the resulting polymer was substantially composed of carbamylethylene, hydroxyamidinoethylene and cyanoethylene linkages in approximately 8:1:1 molar ratio, and was diluted to 5% solids with water and cooled.
  • Dry strength paper containing the resin was made by standard laboratory procedure using 50:50 bleached sulfitezbleached hardwood kraft pulp. The pulp was diluted to 0.6% consistency, aliquots withdrawn, and the polymer solution added with and without alum as shown in the table, the alum when used being added before the polymer. After addition of the polymer the aliquots were gently stirred for 5 minutes and then sheeted on a Nash handsheet machine at 45-50 lb. basis weight (25" x 40/500 ream). The sheets were drum dried for one minute at 250 F. and tested after conditioning at 73 C. and 50% relative humidity for 24 hours.
  • Example 2 The following illustrates the improved results obtained with rosin size when the size is supplied in conjunction with a linear polymer carrying hydroxyamidino groups.
  • the papers were made according to the method of Example 1, wood rosin size and alum being added prior to the polymer. Results are as follows, the first three runs being controls.
  • Example 3 The following illustrates the improvements in dry strength obtained by additional hydroxyamidinoethylene-carbamylethylene polymers.
  • the general method of Example 1 was followed for preparation of the polymers and manufacture of the paper samples, 0.5% of polymer being added to the pulp samples in each instance.
  • Polymers 1-4 were prepared by copolymerizing acrylonitrile and acrylamide and then reacting with hydroxylamine to convert nitrile groups to the proportion of hydroxyamidino groups as shown in the table.
  • polymer No. 1 was prepared by copolymerizing acrylamide and acrylonitrile in 80:20 molar ratio and then reacting with hydroxylamine calculated as equivalent to 75% of the acrylonitrile.
  • Polymer 5 was prepared by copolymerizing acrylamide, acrylonitrile and vinyl acetate in :40:50 molar ratio and then reacting with hydroxylamine to convert 87% 10 I claim:
  • Paper of substantially improved dry strength but of low wet strength composed of a waterlaid web of cellulosic papermaking fibers bonded together by 0.1%- 5%, based on the dry weight thereof, of a normally water-soluble ampholytic linear carbon chain vinyl polymer predominantly composed of recurring hydroxyamidinoethylene and carbamylethylene linkages, the ratio between said linkages being between about 1:100 and 10:1, said polymer having a molecular weight in excess of 100,000.
  • Example 4 Results are as follows. The first four runs are controls.
  • Sized paper of substantially improved dry strength but of low wet strength and of improved resistance to penetration by aqueous fluids composed of a waterlaid web of rosin sized cellulosic papermaking fibers bonded together by 0.1%5%, based on the dry weight of said fibers, of a normally water-soluble ampholytic linear carbon chain vinyl polymer predominantly composed of recurring hydroxyamidinoethylene and carbamylethylene linkages, the ratio between said linkages being between about 1:100 and 10: 1, said polymer having a molecular weight in excess of 100,000 and acting synergistically with said size to render said fibers resistant to penetration by aqueous fluids.
  • Process for the manufacture of paper of substantially improved dry strength but of low wet strength which comprises forming an aqueous suspension of papermaking cellulosic fibers, adding thereto between about 0.1% to 5%, based on the dry weight of the fibers, of a water-soluble ampholytic liner carbon chain vinyl polymer substantially composed of recurring hydroxyamidinoethylene and carbamylethylene linkages, the ratio between said linkages being between about 1:100 and 10:1, said polymer having a molecular weight in excess of 100,000, whereby said polymer is adsorbed on said fibers, sheeting said fibers to form a cellulosic web, and heating said web until dry at a temperature between F. and 250 F.
  • sus 7 pension during addition of the polymer contains between about 0.1% and 2% of alum based on the dry weight of the fibers.

Description

United States Patent DRY STRENGTH PAPER Norman T. Woodberry, Stamford, Conn., assignor to American Cyanamid Company, New York, N.Y., a corporation of Maine No Drawing. Filed Feb. 17, 15758, Ser. No. 715,488
Claims. (Cl. 162-168) erty is particularly desired for conversion into letter paper, check paper, book paper, newspaper and envel- Opes, which do not become wet during normal use.
The discovery has now been made that paper composed of a waterlaid web of cellulosic papermaking fibers bonded together by a small adsorbed amount of a normally water-soluble linear carbon chain polymer con- .taining carbamyl and hydroxyamidino side groups (as more particularly hereinafter described) possesses substantially improved dry strength and yet possesses low wet strength. In preferred instances the dry tensile strength of paper of the present invention is improved by about 50%75% as a result of the strengthening action of the polymer, and dry burst values are improved by upward of 75%85%. On the other hand, the paper '(at ordinary book paper weight) possesses a wet tensile strength of less than about 3 lbs./in., which means that it can be repulped in ordinary papermill equipment.
The polyacrylamidoxime polymer of the present invention is soluble in water yet is substantively adsorbed therefrom by cellulose fibers. Accordingly, paper of the present invention is manufactured by forming an aqueous suspension of papermaking cellulosic fibers, adding thereto a small amount of an aqueous solution of polyacrylamidoxime polymer, sheeting the fibers to form a cellulosic web, and heating the web until dry. The polymers of the present invention are non-thermosetting and thus do not require heat for development of their strengthening properties. However, they are thermostable and thus the wet webs may be dried without harm on steam-heated rolls in the customary temperature range of 190 F. to 250 F.
Only a small amount of polymer need be added. A substantial effect is noted with as little as 0.1% based on the dry weight of the fibers. The strengthening effect levels off when more than about 5% is added, and most efficient use of the polymer is in the range of about 0.5%2% which is therefore preferred.
In the process, the polymer is well adsorbed by fibers which have been rosin sized, and the beneficial effect of the polymer in increasing the dry strength is not significantly v diminished by the presence of such sizing on the fibers.
vention is ampholytic, and thus may be applied as an anionic or cationic material. It is insensitive to pH and affords substantially the same results at pH 6.5 as at pH 3.5. The evidence is that somewhat better dry strength is developed when the pH of the suspension during addition of the polymer is between 4.5 and 6.5, and this range accordingly is preferred.
Best dry strength values are usually obtained when the fibrous suspension during addition of the polymer contains alum. Since the polymer is self-substantive the alum does not appear to act as mordant or precipitant. Evidently the paper produced from suspensions containing alum carries the polymer in the form of an alum complex. About of dissolved alum in the suspension (based on the dry weight of cellulose fibers) is sufiicient to cause a substantial increase in the dry strength imparted by the resin, and more than about 2% appears to be unnecessary for the purpose. An intermediate amount in the range of /;%-1%% is accordingly preferred, it being understood that much larger amounts may be present without harm. With or without alum, adsorption of the polymer by the fibers is substantially complete.
The polymer employed in the present invention consists predominantly of hydroxyamidinoethylene and carbamylethylene linkages,"the theoretical formulaelof which are NH CHzCH(CNHOH)-- and 0 CH CH(CNHa)' The former linkage may exist in the tautomeric form and moreover two adjacent hydroxyamidino substituents may react or coordinate to form ,a linkage of the type to. HON g NOH Paper containing polymers having such linkages is within the scope of the invention.
It is within the scope of the invention to employ polymers containing additional groups which act as diluents, or spacers, or which act in known manner for other purposes. Then the polymer chain may carry in minor, proportion alkyl or aryl, alkoxy, hydroxyl, carboxyl, ester, amine, carboxy, quaternary ammonium, and nitrile groups as supplemental substituents. Up to 50 mol percent of such substituents may be present, it being understood that in the case of the hydrophobic substituents the amounts thereof should be limited so that the polymer remains water-soluble to the extent of at least 5%. p
The hydroxyamidino and carbamyl groups of the polymer are active ionically and evidently serve two principal functions. The first is to provide electrostatic loci, capable of acting ionically by which the polymer macromolecule as a whole is attracted to and substantively adsorbed by cellulose fibers in aqueous suspension in the presence or absence of dissolved polyvalent metal salts. The second function is to provide dry 3 strength. The evidence is that the amide (-NH or =NI-I) component coordinates with the surface of the fibers or the anhydroglucose units therein and is responsible to some extent at least for the dry strength imparted by the polymer.
The hydroxyamidino grouping is effective electrostatically in very small amounts and as little as 1% based on the remaining substituents present has been sufiicient to render the macromolecule cationically active and self-substantive to cellulose. Considerable improvement in the dry strength is obtained by use of polymers containing a larger proportion of these groupings, particularly when the polymer contains hydroxyamidinoethylene and carbamylethylene linkages in ratio between about 1:10 and 3:10. Increasing the proportion of hydroxyamidino groups in the macromolecule results in further improvement in dry strength. This improvement, however, becomes progressively less as the proportion rises above this ratio range and accordingly the range stated is regarded as the practical maximum.
The carbamylethylene linkages which constitute the other major functional grouping in the polymer are ionically inert, but powerfully coordinate or react with the cellulose to provide dry strength. Apparently for the latter purpose they are somewhat more effective than the hydroxyamidinoethylene linkages, and accordingly, the number of carbamylethylene linkages should be at least of the number of hydroxyamidinoethylene linkages. The polymers employed in the present invention may be prepared in any convenient manner. In practice they are most conveniently prepared by copolymerizing a watersoluble vinyl nitrile and a water-soluble vinyl amide in major proportion with or without supplementary or di1uent vinyl material to form an essentially linear carbon chain amide-nitrile polymer. Part or all of the nitrile groups are then reacted with hydroxylamine to form hydroxyamidino groups in the proportion specified. It is preferred to form the polymer by copolymerizing acrylonitrile (methacrylonitrile, crotononitrile, etc.) with acrylamide or similar amide having an unsubstituted -NH amide substituent in molar ratio between about 70:30 and 90:10 and then heating with hydroxylamine to convert nitrile groups to hydroxyamidino groups in proportion specified above. The polymer may be subjected to other reactions before or after the hydroxylamine reaction, and thus any ester groups present may be subjected to hydrolysis to form hydroxy or acid groups; any nitro groups present may be reduced to amine groups; any chloro groups may be reacted with tertiary amines to form quaternary ammonium groups.
The vinyl polymerization leading to formation of the linear chain polymer may be performed in aqueous medium using a redox catalyst, and molecular growth to an advanced stage should be favored. The development of increased dry strength requires the use of polymers having a molecular weight in excess of about 100,000 (as determined by the Staudinger method based on viscosity) and considerably better results are obtained when the molecular weight is upwards of 500,000, which is the preferred lower limit. Generally the polymers are too viscous for commercial use at molecular weights in excess of 5,000,000 and this therefore is the maximum of the preferred range.
The invention will be more particularly described by the examples which follow. These examples illustrate specific embodiments of the invention and are not intended as limitation thereon.
Example 1 The following illustrates the manufacture of paper of excellent dry tensile strength but low wet strength according to the present invention by use of a preferred hydroxyamidinoethylene-carbamylethylene polymer.
The resin was prepared by dissolving 5.0 gm. of an 80%20% (molar ratio) acrylamidezacrylonitrile polymer (molecular weight 500,000) in 200 ml. of water, adding 0.655 gm. of hydroxylamine hydrochloride (equivalent to 64% of the nitrile groups present), adjusting the pH to 6.8 with dilute aqueous NaOH solution, and heating the mixture for 30 minutes at C. The resulting polymer was substantially composed of carbamylethylene, hydroxyamidinoethylene and cyanoethylene linkages in approximately 8:1:1 molar ratio, and was diluted to 5% solids with water and cooled.
Dry strength paper containing the resin was made by standard laboratory procedure using 50:50 bleached sulfitezbleached hardwood kraft pulp. The pulp was diluted to 0.6% consistency, aliquots withdrawn, and the polymer solution added with and without alum as shown in the table, the alum when used being added before the polymer. After addition of the polymer the aliquots were gently stirred for 5 minutes and then sheeted on a Nash handsheet machine at 45-50 lb. basis weight (25" x 40/500 ream). The sheets were drum dried for one minute at 250 F. and tested after conditioning at 73 C. and 50% relative humidity for 24 hours.
Results are as follows.
Paper Pulp Treatment Run No. Pulp Burst Tensile, Lb. lin.
Found, Percent Percent Resin 1 Percent Alum I Dry Wet None None 0. 5 0. 5 0. 5
None None None None 6 0. 5
None 0. 5
I On dry weight of fibers.
1 During addition of polymer solution.
a By TAPPI method.
l Adjusted to 45 lb. basis Weight (25 x 40"]500 ream). 5 Over control (Run N0. 1).
6 Over control (Run No. 2).
7 Over control (Run No. 6).
Example 2 The following illustrates the improved results obtained with rosin size when the size is supplied in conjunction with a linear polymer carrying hydroxyamidino groups. The papers were made according to the method of Example 1, wood rosin size and alum being added prior to the polymer. Results are as follows, the first three runs being controls.
Pulp Treatment 1 Paper Run No. Pulp pH Lactic Acid,
Sec.
Percent Resin Percent Size Percent Alum N one 0. 5 None None None 1. 5
0 Inst. 8 Inst. 5
1 On dry weight of fibers.
I Corrected to a 45 lb. basis weight (25" x 40"]500 ream). 3 Lactic acid resistance; Penescope test.
4 Writing ink penetration resistance.
Example 3 The following illustrates the improvements in dry strength obtained by additional hydroxyamidinoethylene-carbamylethylene polymers. The general method of Example 1 was followed for preparation of the polymers and manufacture of the paper samples, 0.5% of polymer being added to the pulp samples in each instance.
Polymers 1-4 were prepared by copolymerizing acrylonitrile and acrylamide and then reacting with hydroxylamine to convert nitrile groups to the proportion of hydroxyamidino groups as shown in the table. Thus polymer No. 1 was prepared by copolymerizing acrylamide and acrylonitrile in 80:20 molar ratio and then reacting with hydroxylamine calculated as equivalent to 75% of the acrylonitrile.
Polymer 5 was prepared by copolymerizing acrylamide, acrylonitrile and vinyl acetate in :40:50 molar ratio and then reacting with hydroxylamine to convert 87% 10 I claim:
1. Paper of substantially improved dry strength but of low wet strength composed of a waterlaid web of cellulosic papermaking fibers bonded together by 0.1%- 5%, based on the dry weight thereof, of a normally water-soluble ampholytic linear carbon chain vinyl polymer predominantly composed of recurring hydroxyamidinoethylene and carbamylethylene linkages, the ratio between said linkages being between about 1:100 and 10:1, said polymer having a molecular weight in excess of 100,000.
2. Paper according to claim 1 wherein the polymer consists of hydroxyamidinoethylene, carbamylethylene and cyanoethylene linkages.
3. Paper according to claim 1 wherein the ratio of hydroxyamidinoethylene to carbamylethylene linkages is between about 1:10 and 3:10.
1 AOX =hydroxyamldinoethylene; AM carb am ylethylene; CN cyanoethylene.
Example 4 Results are as follows. The first four runs are controls.
Pulp Paper Treatment Pg Run No. p
Per- Per- Dry Dry Fold, cent cent Tensile, Burst, M.I.T Alum 1 Resin 1 Lb./in. Lb./in
0. 5 None 4. 7 12.0 18. 3 11 0.5 None 6. 5 12.3 18. 9 11 2.0 None 4. 7 12. 5 19. 3 13 2. 0 None 6. 5 13. 0 20. 2 14 1 See footnotes to table of Example 1.
The results show that the process is insensitive to pH changes in the range of 3.5 to 6.5 and to the presence of excess alum.
4. Paper according to claim 1 wherein the polymer bonding the fibers is complexed with alum.
5. Sized paper of substantially improved dry strength but of low wet strength and of improved resistance to penetration by aqueous fluids composed of a waterlaid web of rosin sized cellulosic papermaking fibers bonded together by 0.1%5%, based on the dry weight of said fibers, of a normally water-soluble ampholytic linear carbon chain vinyl polymer predominantly composed of recurring hydroxyamidinoethylene and carbamylethylene linkages, the ratio between said linkages being between about 1:100 and 10: 1, said polymer having a molecular weight in excess of 100,000 and acting synergistically with said size to render said fibers resistant to penetration by aqueous fluids.
6. Process for the manufacture of paper of substantially improved dry strength but of low wet strength which comprises forming an aqueous suspension of papermaking cellulosic fibers, adding thereto between about 0.1% to 5%, based on the dry weight of the fibers, of a water-soluble ampholytic liner carbon chain vinyl polymer substantially composed of recurring hydroxyamidinoethylene and carbamylethylene linkages, the ratio between said linkages being between about 1:100 and 10:1, said polymer having a molecular weight in excess of 100,000, whereby said polymer is adsorbed on said fibers, sheeting said fibers to form a cellulosic web, and heating said web until dry at a temperature between F. and 250 F.
7. A process according to claim 6 wherein the cellulosic fibers in the suspension to which the polymer is added are rosin sized.
8. A process according to claim 6 wherein the sus 7 pension during addition of the polymer contains between about 0.1% and 2% of alum based on the dry weight of the fibers.
9. A process according to claim 6 wherein the pH of the suspension during addition of the polymer is between 4.5 and 6.5.
10. A process according to claim 6 wherein the molecular weight of the polymer is between 500,000 and 5,000,000.
References Cited in the file of this patent UNITED STATES PATENTS Thomas Sept. 20, 1955 House et al. Jan. 3, 1956 Gluesenkamp June 11, 1957 Suen et a1. Jan. 21, 1958 Jones Apr. 22, 1958 Fowler et al. May 20, 1958

Claims (1)

  1. 6. PROCESS FOR THE MANUFACTURE OF PAPER OF SUBSTANTIALLY IMPROVED DRY STRENGTH BUT OF LOW WET STRENGTH WHICH COMPRISES FORMING AN AQUEOUS SUSPENSION OF PAPERMAKING CELLULOSIC FIBERS, ADDING THERETO BETWEEN ABOUT 0.1% TO 5%, BASED ON THE DRY WEIGHT OF THE FIBERS, OF A WATER-SOLUBLE AMPHOLYTIC LINER CARBON CHAIN VINYL POLYMER SUBSTANTIALLY COMPOSED OF RECURRING HYDROXYAMIDINOETHYLENE AND CARBAMYLETHYLENE LINKAGES THE RATIO BETWEEN SAID LINKAGES BEING BETWEEN ABOUT 1:100 AND 10:1, SAID POLYMER HAVING A MOLECULAR WEIGHT IN EXCESS OF 100,000 WHEREBY SAID POLYMER IS ADSORBED ON SAID FIBERS, SHEETING SAID FIBERS TO FORM A CELLULOSIC WEB, AND HEATING SAID WEB UNTIL DRY AT A TEMPERATURE BETWEEN 190*F. AND 250*F.
US715488A 1958-02-17 1958-02-17 Dry strength paper Expired - Lifetime US2959514A (en)

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GB4910/59A GB845349A (en) 1958-02-17 1959-02-12 Improved paper and process of producing same
FR786750A FR1225728A (en) 1958-02-17 1959-02-14 Paper having significantly improved dry tensile strength and low wet tensile strength

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE1635555B1 (en) * 1966-11-14 1971-02-04 Du Pont Absorbent, water dispersible nonwoven fabric and method for making the same
US3966694A (en) * 1973-02-21 1976-06-29 Hercules Incorporated Cationic water soluble polymeric reaction product of poly(diallylamine)-epihalohydrin and nitrogen compound
US4632984A (en) * 1985-05-02 1986-12-30 Kyoritsu Yuki Co., Ltd. Process for the production of cationic starch

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US2718515A (en) * 1954-08-13 1955-09-20 American Cyanamid Co Copolymers of n-substituted acrylamides
US2729560A (en) * 1953-06-22 1956-01-03 American Cyanamid Co Wet strength paper containing aminoaliphatic chain polymer resins
US2795545A (en) * 1953-04-14 1957-06-11 Monsanto Chemicals Organic materials
US2820777A (en) * 1954-04-29 1958-01-21 American Cyanamid Co Process of preparing polyacrylamide
US2831841A (en) * 1956-03-19 1958-04-22 Dow Chemical Co Treatment of acrylamide polymers
US2835582A (en) * 1954-02-03 1958-05-20 Eastman Kodak Co Gelatin-polymeric hydrosol mixtures and photographic articles prepared therefrom

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Publication number Priority date Publication date Assignee Title
US2795545A (en) * 1953-04-14 1957-06-11 Monsanto Chemicals Organic materials
US2729560A (en) * 1953-06-22 1956-01-03 American Cyanamid Co Wet strength paper containing aminoaliphatic chain polymer resins
US2835582A (en) * 1954-02-03 1958-05-20 Eastman Kodak Co Gelatin-polymeric hydrosol mixtures and photographic articles prepared therefrom
US2820777A (en) * 1954-04-29 1958-01-21 American Cyanamid Co Process of preparing polyacrylamide
US2718515A (en) * 1954-08-13 1955-09-20 American Cyanamid Co Copolymers of n-substituted acrylamides
US2831841A (en) * 1956-03-19 1958-04-22 Dow Chemical Co Treatment of acrylamide polymers

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE1635555B1 (en) * 1966-11-14 1971-02-04 Du Pont Absorbent, water dispersible nonwoven fabric and method for making the same
US3966694A (en) * 1973-02-21 1976-06-29 Hercules Incorporated Cationic water soluble polymeric reaction product of poly(diallylamine)-epihalohydrin and nitrogen compound
US4632984A (en) * 1985-05-02 1986-12-30 Kyoritsu Yuki Co., Ltd. Process for the production of cationic starch
AU573366B2 (en) * 1985-05-02 1988-06-02 Kyoritsu Yuki Co. Ltd. Amidoximated starch

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