EP1044300A1 - Method for making a cellulosic web with improved wet-tensile strength - Google Patents

Abstract

A method of improving the wet-tensile strength of a cellulosic web including providing a papermaking furnish containing a cellulosic material and water; adding a surfactant to the papermaking furnish; and adding a wet strength resin to the papermaking furnish after addition of the surfactant. In certain implementations, the surfactant includes an alkyl sulfate or an alkyl sulfonate. The method provides an improved cellulosic web haing improved wet/dry tensile ratio.

Description

METHOD FOR MAKING A CELLULOSIC WEB WITH IMPROVED WET-TENSILE STRENGTH

Technical Field

This invention relates generally to an absorbent web and a method for

preparing the absorbent web. More particularly, the invention relates to a cellulosic

web having improved wet-tensile characteristics and methods for making the same.

Background

Cellulosic web-based products, such as hand towels, wipers, and the like, are

widely manufactured in the paper making industry. Each product has unique

characteristics requiring appropriate attributes. The proper attributes ensure that the

product is suitable for its intended purpose. For many products, these attributes

include high tensile strength and high water absorbency.

Tensile strength of cellulosic webs is often measured under dry conditions to

determine "dry-tensile strength", and under wet conditions to determine "wet-tensile

strength". Wet-tensile strength and dry-tensile strength are often closely related.

Products having high dry-tensile strength frequently have high wet-tensile strength.

The relationship between dry-tensile strength and wet-tensile strength occurs, in

part, because certain manufacturing processes enhance both properties. For

example, pressing a cellulosic web under high pressure often imparts increased dry-

tensile and wet-tensile strengths.

A cellulosic web must have adequate dry-tensile strength and adequate wet-

tensile strength. However, since cellulosic webs often deteriorate and lose strength when wet, wet-tensile strength is normally significantly lower than dry-tensile

strength. Thus, many cellulosic webs have inadequate wet-tensile strength, even

though they have adequate dry-tensile strength.

While a hand towel must have some dry-tensile strength, high dry-tensile

strength can be disadvantageous because it correlates closely with stiffness and stiff

webs. Hand towels manufactured from stiff webs are received with disfavor by

consumers, since the towels do not have the soft feel of traditional cotton hand

towels. In contrast, consumers desire high wet-tensile strength, because it allows

more vigorous use of the hand towel to pick up spills and scrub wet soiled surfaces.

Traditionally, the wet-tensile strength of hand towels is improved by using increased

pressure or a wet strength resin. While these methods increase the wet strength of

the hand towels, they usually also increase the dry strength. For example, the

addition of CMC (carboxymethyl cellulose) causes significant increases in both wet

tensile and dry tensile strengths.

The relationship between wet-tensile and dry-tensile is often expressed as a

tensile strength ratio in which wet-tensile strength is divided by dry-tensile strength

to get the wet/dry tensile ratio (wet-tensile value in numerator, dry-tensile value in

denominator). The wet/dry tensile ratio is normally less than 0.3, since the wet-

tensile strength is usually significantly less than the dry-tensile strength. The ratio is

preferably as close to 1 as possible, since this indicates a high wet-tensile strength

relative to dry-tensile strength. Cellulosic webs with high wet/dry tensile ratios are

soft, yet strong. Therefore, a need exists for an improved cellulosic web that has high wet-

tensile strength and a high wet/dry tensile ratio.

Summary of the Invention

The present invention provides an improved method for making a cellulosic

web, as well as a web made using the improved method. The method includes

addition of surfactant and wet strength resin to a papermaking furnish. The resulting

papermaking furnish is formed into a cellulosic web that is dried in accordance with

conventional paper making methods. The finished web has improved strength

properties. In a certain implementation, the finished web has improved wet-tensile

strength and an improved wet/dry tensile ratio.

A specific implementation of the method of the invention includes providing

a papermaking furnish containing a cellulosic material and water. Surfactant is

added to the papermaking furnish. A wet strength resin is added to the papermaking

furnish after addition of the surfactant. In a specific implementation, the surfactant

includes a sulfonate, such as the surfactant Witco 5175-26 A, sold by the Witco

Chemical Co. Following addition of the surfactant, the cellulosic material is

removed from the papermaking furnish to form a cellulosic web. A high percentage

of the wet strength resin that was added to the papermaking furnish is retained by the

cellulosic web. Finally, the cellulosic web is dried and formed into finished

products, such as hand towels. The resulting web has improved wet-tensile strength

as well as an improved the wet/dry tensile ratio. The above summary of the present invention is not intended to describe each

discussed embodiment of the present invention. While the invention is susceptible

to various modifications and alternative forms, specifics thereof will be described in

detail. It should be understood, however, that the intention is not to limit the

invention to particular embodiments described. On the contrary, the intention is to

cover modifications, equivalents, and alternatives falling within the spirit and scope

of the invention as defined by the appended claims.

Detailed Description

The present invention is directed to an improved method for making a

cellulosic web, as well as a web made using the improved method. The method

includes addition of surfactant and wet strength resin to a papermaking furnish. The

resulting papermaking furnish is formed into a cellulosic web. This web is

subsequently dried in accordance with conventional paper making methods. The

finished web has improved strength properties, for example, improved wet-tensile

strength and an improved wet-tensile strength to dry-tensile strength ratio (wet/dry

tensile ratio).

The method includes providing a papermaking furnish containing a cellulosic

material and water. The cellulosic material is, for example, Northern Soft Wood

Kraft (NSWK), chemi-thermo-mechanical pulp (CTMP), natural redwood (RW),

Mobile Pine (MP), or a recycled wood fiber, such as bleached recycled office waste

fiber. Surfactant is added to the papermaking furnish and a wet strength resin is

added after the addition of the surfactant. When an appropriate surfactant is added

to the papermaking furnish, the quantity of wet-strength resin added to the furnish

may be greatly reduced without sacrificing wet-tensile strength. When even very

low levels of surfactant are added, marked enhancements to the wet-tensile strength

of the resulting web are observed. In some such implementations, the wet-tensile

strength increases significantly while the dry-tensile strength decreases. This

resulting cellulosic web shows improved softness and wet-strength properties.

While the present invention is not limited to a specific surfactant, one

appropriate surfactant is Witco 5175-26A, manufactured by the Witco Chemical Co.

Witco 5175-26A includes a significant sulfonate component. Preferred surfactants

include an anionic alkyl sulfate or anionic alkyl sulfonate component. Acceptable

surfactants include Witco EP-5327-97 and EP-5293-150, also manufactured by the

Witco Chemical Co. In addition to the anionic alkyl sulfate or anionic alkyl

sulfonate component, the surfactant may include other wetting agents to improve

water compatibility and absorbency on the fiber.

The quantity of surfactant added to the papermaking furnish is between 0.1

and 10.0 pounds per ton of cellulosic material. In specific implementations, the

quantity is from 0.5 to 5.0 pounds per ton. In yet another implementation, the

quantity is between 0.5 and 2.5 pounds per ton of cellulosic material. The quantity

is approximately 1.0 pounds per ton in specific implementations in which the

cellulosic material is primarily NSWK fibers. Following addition of the surfactant, a wet strength resin is added to the

papermaking furnish. The wet-strength resin provides a binding force securing the

cellulosic web when wet. The wet-strength resin is preferably water soluble.

Suitable resins include polyamide-epichlorohydrin resins such as those sold by

Hercules Incorporated of Wilmington, Delaware, under the brand name Kymene

557H and Kymene 2064. These resins include low molecular weight polymers

having reactive functional groups, including epoxy and amino groups.

The wet-strength resin is added at a rate of between 5.0 and 30.0 pounds per

ton of cellulosic material. While the complete mechanism of the present invention is

not fully understood, without limiting the invention, it is believed that the addition

of the surfactant to the papermaking formulation provides greater absorbency or

functionality of the wet-strength resin. The improved absorbency or functionality of

the wet-strength resin allows for use of reduced wet-strength resin.

After addition of the surfactant and wet-strength resin, the cellulosic material

is removed from the papermaking furnish to form a cellulosic web. A high

percentage of the wet strength resin added to the papermaking furnish is retained by

the cellulosic material as the cellulosic web is formed. In specific implementations,

at least 80 percent of the wet strength resin is secured to the cellulosic web. The

cellulosic web is then dried and formed into finished products, such as hand towels.

The resulting cellulosic web has improved wet-tensile strength as well as an

improved ratio of wet-tensile strength to dry-tensile strength . Referring now to the tables produced below, example formulations of cellulosic webs constructed in

accordance with the present invention are shown.

Each table shows five different formulations of cellulosic webs. The

summary data shown reflects the averaged values for eight different samples of each

formulation. In producing each formulation, a cellulosic fiber feed stock was added

and mixed with water to form a papermaking formulation. A surfactant and wet

strength resin were sequentially added (in the orders, as indicated). A cellulosic web

formed from the papermaking formulation was dried, and the resulting dried web

was tested for wet-tensile strength and dry-tensile strength according to paper testing

methods on Instron and Twing- Albert tensile testing instruments.

Table 1 A: Addition of Surfactant followed by Wet Strength Resin to NSWK feed stock.

NSWK = Northern Softwood Kraft

WSR = Wet strength resin

Witco = Surfactant containing sulfonate manufactured by Witco Chemical Co., sold under the name Witco 5175-26A

First Additive Dose and Second Additive Dose are measured in pounds of additive to pound of feed stock.

Table 1A shows that addition of a surfactant prior to addition of the wet-

strength resin results in an increase in wet-tensile strength and an increase in the

wet/dry tensile ratio when applied to NSWK feed stock. Formulation 1, which is the

control in which no surfactant was added, has a significantly lower wet/dry tensile

ratio and lower wet-tensile strength than formulations 2, 3, 4, and 5, in which the

surfactant Witco 5175-26 A was added first. Table IB: Addition of Wet Strength Resin followed

by Surfactant to NSWK Feedstock

NSWK = Northern Softwood Kraft

WSR = Wet strength resin

Witco = Surfactant containing sulfonate manufactured by Witco Chemical Co., sold under the name Witco 5175-26A

First Additive Dose and Second Additive Dose are measured in pounds of additive to pound of feed stock.

Table IB, when compared with Table 1 A, demonstrates the importance of

adding surfactant prior to adding the wet strength resin to NSWK feed stock. In

Table IB, the formulations have a first additive of the wet strength resin and a

second additive of the Witco 5175-26A surfactant. Compared to formulations from

Table 1A using the same dosage and different order of addition, the formulations in

Table IB have significantly lower wet-tensile strength and wet/dry tensile ratios. Table 2A

NSWK = Northern Softwood Kraft

WSR = Wet strength resin

Witco = Surfactant containing sulfonate manufactured by Witco Chemical Co., sold under the name Witco 5175-26A

First Additive Dose and Second Additive Dose are measured in pounds of additive to pound of feed stock.

Table 2A shows significant increase in the wet/dry tensile ratios in

formulations 2, 3, 4, and 5 compared to formulation 1. The difference in the

formulations is that a surfactant was not used in formulation 1 , but was used in

formulations 2, 3, 4, and 5.

Table 2B

NSWK = Northern Softwood Kraft

WSR - Wet strength resin

Witco = Surfactant containing sulfonate manufactured by Witco Chemical Co., sold under the name Witco 5175-26A

First Additive Dose and Second Additive Dose are measured in pounds of additive to pound of feed stock.

The formulations of Table 2B, compared to the formulations of Table 2 A,

show that order of addition of the surfactant containing a sulfonate influences the

wet/dry tensile ratios, and that the ratio is improved by adding the wet-strength resin

after addition of the surfactant.

Table 3A: Addition of Surfactant followed by Wet Strength

Resin to Bleached Recycled Office Waste Fiber Feed stock

RO = Bleached recycled office waste fiber

WSR = Wet strength resin

Witco = Surfactant containing sulfonate manufactured by Witco Chemical Co., sold under the name Witco 5175 -26 A

First Additive Dose and Second Additive Dose are measured in pounds of additive to pound of feed stock.

Tables 3 A and 3B show that even very low levels of surfactant can

dramatically increase the wet-tensile strength of recycled office waste fiber feed

stock.

Table 3B: Addition of Wet Strength Resin followed by Surfactant to Bleached Recycled Office Waste Fiber Feed Stock

RO = bleached recycled office waste fiber

WSR = Wet strength resin

Witco = Surfactant containing sulfonate manufactured by Witco Chemical Co., sold under the name Witco 5175-26A

First Additive Dose and Second Additive Dose are measured in pounds of additive to pound of feed stock.

While the present invention has been described with reference to several

particular implementations, those skilled in the art will recognize that many changes

may be made hereto without departing form the spirit and scope of the present

invention.

Claims

I CLAIM:

1. A method of improving the wet-tensile strength of a cellulosic web, the

method comprising:

providing a papermaking furnish containing a cellulosic material and water;

adding a surfactant to the papermaking furnish; and

adding a wet strength resin to the papermaking furnish after addition of the

surfactant.

2. The method of improving the wet-tensile strength of a cellulosic web

according to claim 1, wherein the surfactant includes an alkyl sulfonate or an alkyl

sulfate.

3. The method of improving the wet-tensile strength of a cellulosic web

according to claim 1 , wherein the surfactant is selected from the group consisting of

Witco 5175-26A, Witco EP-5327-97; Witco EP-5293-150, and combinations

thereof.

4. The method of improving the wet-tensile strength of a cellulosic web

according to claim 1, wherein the wet-strength resin is added at a rate of between 5.0

and 25.0 pounds per ton of cellulosic material.

5. The method according to claim 1, wherein the surfactant is added at a rate of

less than about 10 pounds per ton of cellulosic material.

6. The method according to claim 1 , wherein the surfactant is added at a rate of

less than about 5 pounds per ton of cellulosic material.

7. The method according to claim 1, wherein:

the surfactant is added to the papermaking furnish at a rate of between 0.5

and 5 pounds per ton of cellulosic material; and

the wet strength resin is added at a rate of 0.5 to 15 pounds per ton of

cellulosic material.

8. The method according to claim 1, further comprising:

formation of a cellulosic web by removal of a significant majority of the

cellulosic material from the papermaking finish;

wherein at least 80 percent of the wet strength resin is secured to the

cellulosic web.

9. A method of improving the wet-tensile strength of a cellulosic web, the

method comprising:

providing a papermaking furnish containing a cellulosic material and water; adding between 0.5 and 5.0 pounds of a surfactant to the papermaking

furnish per ton of cellulosic material; and

adding between 5.0 and 25.0 pounds of a wet strength resin to the

papermaking furnish per ton of cellulosic material after adding the surfactant.

10. The method according to claim 9, further comprising:

formation of a cellulosic web by removal of a significant majority of the

cellulosic material from the papermaking finish;

wherein at least 80 percent of the wet strength resin is secured to the

cellulosic web.

11. The method according to claim 9, wherein the surfactant includes a sulfonate.

12. The method according to claim 9, wherein the papermaking furnish

comprises fibers selected from the group consisting of northern softwood kraft,

bleached recycled fiber, unbleached recycled fiber, chemical-thermo-mechanical

pulp, and southern softwood kraft.

13. A method of improving the ratio of wet-tensile strength to dry-tensile

strength of a cellulosic web, the method comprising:

providing a papermaking furnish of cellulosic material and water;

adding a surfactant to the papermaking furnish; and adding a wet strength resin to the papermaking furnish after addition of the

surfactant;

wherein the ratio of wet-tensile strength to dry-tensile strength is greater than

0.20.

14. The method of improving the ratio of wet-tensile strength to dry-tensile

strength of a cellulosic web according to claim 13, wherein the ratio of wet-tensile

strength to dry-tensile strength is greater than 0.50.

15. The method of improving the ratio of wet-tensile strength to dry-tensile

strength of a cellulosic web according to claim 13, wherein the surfactant contains a

sulfonate.

16. The method of improving the ratio of wet-tensile strength to dry-tensile

strength of a cellulosic web according to claim 13, wherein the surfactant is Witco

5175-26A.

17. A method of improving the ratio of wet-tensile strength to dry-tensile

strength of a cellulosic web, the method comprising:

providing cellulosic material;

combining the cellulosic material with water to form a papermaking furnish; adding between 0.5 and 5.0 pounds of a sulfonate-containing surfactant per

ton of cellulosic material to the papermaking furnish; and

after adding the surfactant, adding between 5.0 and 25 pounds of wet

strength resin per ton of cellulosic material to the papermaking furnish.

18. The method according to claim 17, further comprising:

formation of a cellulosic web by removal of at least 90 percent of the

cellulosic material from the papermaking finish;

wherein at least 80 percent of the wet strength resin added to the

papermaking finish is secured to the cellulosic web.

19. The method according to claim 17, wherein the web is formed by a through

dried process without creping.

20. The method according to claim 17, wherein the web is formed by wet press

and crepe transfer technique.

21. A cellulosic web having improved wet-tensile strength formed by the method

of claim 1.