Method for improving the tuft bind of textile coverings

The present invention is directed toward a method for improving the tuft bind of yarn in textile coverings. The method comprises applying to the yarn, prior to applying an adhesive, a functional amount of an aqueous dispersion comprising a surfactant and/or polymeric component wherein the aqueous dispersion has a surface tension approximately equal to or less than the surface tension of the yarn. The present invention also is directed toward a textile covering having improved tuft bind prepared by the aforementioned method. The method is advantageously employed in the preparation of floor coverings to maintain the original appearance and resist the loss of pile or a condition known as pill and fuzzing.

BACKGROUND OF THE INVENTION 
The present invention is directed toward a method for improving the 
penetration of latex adhesives into yarn present in the backing of a 
textile covering such that the tuft bind of the yarn is improved. Tuft 
bind is the force required to remove the yarn or single filament thereof 
from a backing material. 
The satisfactory performance of a textile covering, such as a floor 
covering, depends to a considerable extent on the maintenance of the 
original appearance of the textile covering. In a tufted, knitted or woven 
pile textile covering, an inadequate tuft bind may result in complete loss 
of the pile in the areas exposed to severe wear or a condition known as 
pill and fuzzing. Pill and fuzzing are the result of the individual 
filaments of a yarn being gradully displaced from the yarn. In more severe 
cases a tufted, knitted or woven pile textile covering with inadequate 
tuft bind may have the individual yarns pulled out to form unsightly long 
tufts or occassionally develop hazardous loops. It is therefore very 
desirable to improve the tuft bind of the individual yarns in the backings 
of the textile coverings. 
More recently, new and improved yarns have been developed for use in the 
carpet industry and/or pile floor covering industry which are specifically 
designed to be soil resistant, static resistant, mold and mildew resistant 
and stain resistant. Whereas, the improved yarns are advantageous over the 
old yarns, they do present manufacturing problems. In particular, the 
yarns, while being resistant to the passage of foreign materials, are also 
therefore resistant to the latex adhesive necessary to firmly bind it to 
the backing of the textile covering. Thus, the new yarns resist the 
penetration of latex adhesives which therefore results in poor tuft bind. 
Accordingly, the appearance of the tufted, knitted or woven textile 
covering made with the newer yarns are very susceptible to loss of pile in 
areas exposed to severe wear and pill and fuzzing. It is therefore 
desirable to develop a method for improving the tuft bind of not only 
conventional yarns but the new yarns which are resistant to the passage of 
foreign materials. 
SUMMARY OF THE INVENTION 
In one aspect, the present invention is a method for improving penetration 
of an adhesive into yarn present on the backing of a textile covering. The 
method is characterized by applying to the yarn, prior to applying an 
adhesive, a functional amount of an aqueous dispersion having a surfactant 
and/or a polymeric component. The aqueous dispersion has a surface tension 
approximately equal to or less than the surface tension of the yarn. 
Where the aqueous dispersion contains a polymeric component or polymeric 
and surfactant components, they are generally present in amounts up to 
about 50 percent, more preferably 10 to about 30 percent by total weight 
of the aqueous dispersion. Where the aqueous dispersion contains only a 
surfactant, it is generally present in an amount of from about 0.02 to 
about 2 percent, more preferably 0.05 to about 0.5 percent by total weight 
of the aqueous dispersion. Preferred surfactants are fluorocarbon 
surfactants. 
An aqueous dispersion containing a polymeric component or polymeric and 
surfactant component is generally applied to the backing in an amount of 
from about 0.25 to about 25 oz/yd.sup.2, more preferably 1 to about 5 
oz/yd.sup.2 on a dry basis. An aqueous dispersion containing only a 
surfactant component is applied to the backing in an amount of from about 
0.001 to about 2 oz/yd.sup.2, preferably 0.005 to about 0.5 oz/yd.sup.2 on 
a dry basis. The preferred method of applying the aqueous dispersion is by 
a spray application means. 
In another aspect, the present invention is directed toward a textile 
covering having improved tuft bind prepared by applying to the yarn 
present on the backing of a textile covering an aqueous dispersion 
comprising a surfactant and/or a polymeric component prior to the 
application of an adhesive. The aqueous dispersion has a surface tension 
approximately equal to or less than the surface tension of the yarn 
employed in the preparation of the textile covering whereby the 
penetration of the adhesive into the yarn is improved. The yarn which 
makes up the textile covering can be any of a variety of synthetic and 
natural yarns such as nylon, polypropylene, acrylic, polyester, cotton or 
wool. 
Textile coverings prepared by the present invention are resistant to having 
the yarns pulled from the backing and are resistant to a condition known 
as pill and fuzzing. Thus, the present invention provides an improved 
method for preparing a textile covering having increased durability and 
resistance to severe wear. The present invention is especially adaptable 
for use in the manufacture of tufted floor coverings. 
DETAILED DESCRIPTION OF THE INVENTION 
The present invention provides for an improvement in the tuft bind of 
tufted, knitted or woven textile coverings (hereinafter jointly referred 
to as "tufted"). Generally, the method for improving tuft bind involves 
the application of an aqueous dispersion containing a surfactant and/or 
polymeric component to the textile backing prior to applying the adhesive 
material. The aqueous dispersion is formulated such that it facilitates 
the flow or uptake of the subsequently applied adhesive material into the 
yarn or tuft. The ability of the subject aqueous dispersion to assist in 
the transfer of adhesive to fabric filaments or yarns is especially of 
value where the primary backing is not a smooth surface but rather a rough 
texture or undulated surface. 
Tuft is defined as the cut or uncut loops of yarn formed from fabric 
filaments which thus form the textile surface. The fabric filaments or 
yarn are woven, needle punched, stitched or otherwise mechanically affixed 
to a primary backing. It is to the underside of this primary backing that 
the application of the aqueous dispersion is made. The subject aqueous 
dispersion has an affinity for the particular fabric filaments employed 
which serve to allow the subsequently applied adhesive material to be 
taken up by or penetrate the individual filaments of the yarn. 
The characteristic of transporting the adhesive material up to or into the 
filament greatly enhances their adhesion to the filaments and yarns to 
themselves and to the primary backing and respectively to the secondary 
backings. Typically, the secondary backings are coarse, textile fabric 
laminated to the primary backing to reinforce the latter. The aqueous 
dispersion which is applied to the primary backing is specially formulated 
to have a surface tension approximating or less than that of the yarn. 
Generally, the aqueous dispersion is formulated by adding a functionally 
effective amount of a surfactant and/or polymeric material which is 
compatible with the adhesive coating to be applied and which itself has a 
surface tension approximating or less than that of the yarn. 
Typically, when a polymeric component or both a polymeric and a surfactant 
component are employed in the aqueous dispersion, they are present in an 
amount of up to about 50 percent, preferably 10 to 30 percent by total 
weight of the aqueous dispersion. When only a surfactant component is 
employed, it is generally present in an amount of from about 0.02 to about 
2.0 percent, preferably from about 0.05 to about 0.5 percent by total 
weight of the aqueous dispersion. 
An important aspect in the preparation of the aqueous dispersion is that 
the surfactant or polymeric component employed has a surface tension 
approximately equal to or less than the yarn to be treated. For example, 
fluorocarbon surfactants having a low surface tension of from about 12 to 
about 30 dynes are very good choices because their surface tension is 
generally lower than most yarns commonly employed in the manufacture of 
textile coverings. 
Other surfactants having similarly low surface energy can also be employed. 
Surface energy values are generally available from references such as 
Skeist, Handbook of Adhesives, chapter 3 (2nd Ed. 1977); Shafrin, Polymer 
Handbook, "Critical Surface Tensions of Polymers" (2nd Ed. 1975); ACS, 
Chemistry and Physics of Interfaces, (1965). 
In addition to the surfactant, a polymeric component, for example a latex 
compatible with the latex adhesive to be subsequently applied, can be 
incorporated into the aqueous dispersion. This can improve the uptake of 
substantially applied adhesive into the yarn's filaments. Thus, the 
practitioner of the present invention will choose a surfactant and/or 
polymeric component having a surface tension approximately equal to the 
yarn to be employed in the preparation of the textile covering. The 
surfactant and/or polymeric component is then admixed into water to form 
an aqueous dispersion in an amount as defined above. 
After the aqueous dispersion is prepared, it is applied to the backing of 
the textile material in a functionally effective amount such that the 
penetration of the subsequently applied adhesive is improved. Generally, 
an aqueous dispersion having a polymeric or both a polymeric and 
surfactant component is applied to the backing in an amount from about 
0.25 to about 25 oz/yd.sup.2 on a dry basis, preferably from about 1 to 
about 5 oz/yd.sup.2 on a dry basis. Typically, an aqueous dispersion 
having only a surfactant component is applied to the backing in an amount 
from about 0.001 to about 2 oz/yd.sup.2 on a dry basis, more preferably in 
an amount of from about 0.005 to about 0.5 oz/yd.sup.2 on a dry basis. 
The aqueous dispersion can be applied to the backing of the textile 
covering by any convenient method such that the yarns are wetted. Typical 
methods may include brush, roller, or more preferably a spray. Generally, 
the application is performed as close to the application of the adhesive 
as is possible or such that the aqueous dispersion is not completely lost 
via evaporation prior to the application of the adhesive. 
The subject method for improving the penetration of a latex adhesive into 
the yarn present on the backing of a textile covering is especially 
adaptable for use in the preparation of quality pile floor coverings, 
especially when employing yarns treated to be resistant to foreign 
materials. Many varieties of synthetic and natural yarns can be treated by 
the subject aqueous dispersion for better tuft bind such as nylon, 
polypropylene, acrylic, polyester, wool or cotton.

EXAMPLE I 
An aqueous dispersion was prepared having 0.1 percent by total weight of a 
fluorocarbon surfactant dispersed therein. The fluorocarbon surfactant had 
a surface tension value of 18.5 dynes/cm at a one percent concentration at 
25.degree. C. The aqueous dispersion also had a surface tension of 
approximately 18.5 dynes/cm. 
The aqueous dispersion was applied to the backing of a tufted pile floor 
covering which was prepared from nylon yarn having a surface tension of 
about 40 to 44 dynes/cm. One-half of the floor covering material was 
untreated and one-half was treated with the subject aqueous dispersion. 
The aqueous dispersion was applied to the treated covering material at a 
rate of 0.008 oz/yd.sup.2 on a dry basis. After applying the aqueous 
dispersion, a latex adhesive was blade coated onto the backing material 
and a secondary backing applied. The carpet section was then dried in an 
oven. After the carpet section was completely dried, a visual inspection 
showed no difference between the section of the carpet treated with the 
aqueous dispersion and the section that was not treated with the aqueous 
dispersion. 
The section was then subjected to a tuft bind test which consisted of 
running a velcro brush over the surface of the carpet. After one pass of 
the velcro brush, the untreated section showed considerable pill and 
fuzzing; whereas, the treated section maintained its original appearance. 
This test demonstrates the improvement of tuft binding in the carpet 
section treated with the subject aqueous dispersion. 
EXAMPLE II 
An aqueous dispersion was prepared having both a polymeric and surfactant 
component dispersed therein. The polymeric component consisted of a latex 
of 35 parts vinylidene chloride, 36 parts butadiene and 27 parts styrene. 
The latex was added to the aqueous dispersion in an amount of 26 percent 
by total weight of said aqueous dispersion and had a surface energy value 
of about 40 dynes/cm. The amount of latex was calculated on the basis of 
dry parts. A surfactant component was also added to the aqueous dispersion 
in an amount of 0.2 percent by total weight of the aqueous dispersion. The 
surfactant was a fluorocarbon surfactant and had a surface tension value 
of approximately 18.5 dynes/cm at a 1 percent concentration at 25.degree. 
C. The total surface tension of the aqueous dispersion was approximately 
25 dynes/cm. 
The aqueous dispersion was thoroughly mixed and was applied to the backing 
of a tufted pile floor covering which was prepared from nylon yarn having 
a surface tension of about 40 to 44 dynes/cm. One portion of the floor 
covering material was untreated and an adjacent portion was treated with 
the subject aqueous dispersion. The aqueous dispersion was applied at a 
rate of 2 oz/yd.sup.2 on a dry basis. After the application of the aqueous 
dispersion, a latex adhesive was coated onto the backing material and a 
secondary backing applied. The carpet section was then dried in an oven. 
After the carpet section was completely dried, a visual inspection showed 
no difference between the section of carpet treated with the aqueous 
dispersion and the section that was not treated with the aqueous 
dispersion. 
The tuft bind of the carpet sections was measured by employing the standard 
test method for tuft bind of pile floor coverings ASTM D-1335-67. The 
method consisted of measuring the force required to pull a cut loop from 
the carpet section. The required load or force is reported in pounds-force 
(lbf). For the untreated carpet section, a 5.0 lbf was required to pull a 
loop from the backing of the carpet. For the trated carpet section, a 7.1 
lbf force was required to pull a loop from the carpet backing. This 
represents a 42 percent increase in tuft bind for the section of the 
carpet treated by the method of the subject invention versus the 
unntreated carpet section. Therefore, with all other parameters being held 
equal, the application of the present aqueous dispersion to the yarn 
present on the backing prior to the application of the latex adhesive had 
a significant effect upon the improvement of tuft bind.