US3410077A

US3410077A - Bulky yarn

Info

Publication number: US3410077A
Application number: US245880A
Authority: US
Inventors: Marzocchi Alfred; Gustav E Benson; Roger W Roth
Original assignee: Owens Corning Fiberglas Corp
Current assignee: Owens Corning
Priority date: 1962-12-19
Filing date: 1962-12-19
Publication date: 1968-11-12
Anticipated expiration: 1985-11-12

Description

BULKY YARN Filed Dec. 19, 1962 3 Sheets-Sheet l I I? a: I l I Ennn Im INVENTORS "MM/XIII! ALF/e50 MARZOCCHI, Gusmv E BENSON Reef/e W. ROTH Nov. 12, 1968 A. MARZOCCHI ETAL 3,410,077

BULKY YARN Filed DEC. 19 1952 3 Sheets-Sheet 2 ALF/e50 MAAZOCCHI,

61/57/14/ 5. Bf/VSO/V &

ROGER MA ROTH INVENTORS ATTORNEY-5 1968 A. MARZOCCHI ETAL 3,410,077

BULKY YARN Filed Dec. 19, 1962 s Sheets-Sheet s flLFms-o Mwzoccw, Gusmv 5 55/1/50 &

Roe/5R n4 ROTH INVENTORS wa 42M Arm/Hwy:

United States Patent 3,410,077 BULKY YARN Alfred Marzocchi, Cumberland and Gustav E. Benson,

Greenville, R.I., and Roger W. Roth, Granville, Ohio,

assignors to Owens-Corning Fiberglas Corporation, a

corporation of Delaware Filed Dec. 19, 1962, Ser. No. 245.880 9 Claims. (Cl. 57-144) This invention relates to bulky yarns and to apparatus and methods for their production. More particularly, this invention relates to bulky yarns made from a plurality of strands of continuous glass fibers wherein loop yarns are produced with the loops thereof expanded to filamentized form. Thus, novel products are made in accordance with the present invention and novel methods and apparatus are inherent in their production.

THE ESSENCE OF THE PRIOR ART It is well recognized in the prior art that unusual textured fabrics can be produced from novelty yarns such as loop and boucle yarns wherein the yarns are characterized by loops of a second yarn carried upon a first or tensioned carrier yarn. A loop yarn is self-descriptive, and a bocle has a third spiral wrapped strand to hold the loop strand to the carrier strand.

Other novelty yarns include slub yarns having inserted tufts or balls of loose yarn incorporated into a base yarn; and knop yarns having enlarged knobs formed by twisting one yarn end about another end many times within a very short space, causing enlargements on the surface of the yarn.

THE PROBLEM From the foregoing it will be noted that these prior art novelty yarns have used either tight loops, as in a loop yarn; tight loops held by a binder yarn, as in a boucle; tufted balls of loose yarn that are partly concealed by insertion in a base yarn, to wit, a slub; or the tight exposed knobs of the knop yarn.

To provide greater esthetic appeal, the novel yarns should display wool-like resilient knubs along the length of the base yarn. Thus, the prior products do not display a truly wool-like characteristic of many exposed or fiuifed fibers at the loops. Thus, none of the prior yarns are fully filamentized at the loops to form a truly wool-like product.

Accordingly, novelty yarns displaying a truly wool-like resilient loop characteristic along the length that is adapted to processing by conventional looms would provide a substantial advancement in the art. Apparatus and method for the production of such products would also provide a substantial contribution to the art.

Accordingly, it is an important object of the present invention to provide novel bulky yarns.

Another object is to provide a method for producing the novel bulky yarns.

A further object is to provide apparatus for producing the novel bulky yarns.

A further object is to provide a novelty loop yarn wherein the loops are filamentized.

A further object is to provide a novelty loop yarn of continuous fibers wherein the loops are filamentized.

A further object is to provide a novelty loop yarn comprising at least two strands of continuous fibers, one a so-called tensioned or carrier strand and the other a looped strand on the carrier strand with the looped strand filamentized at least at the bight of the loops.

Anther object is to provide a method for producing novelty loop yarns from strands wherein the looped yarn is filamentized at the point of incorporation into the finished product.

A further object is to provide a method of forming 3,410,077 Patented Nov. 12, 1968 ice novelty loop yarns from continuous glass strands wherein all fibers going into the product are placed under a constant tension during production and thus are of uniform size as distinguished from forming processes for analogous products in the prior art.

Another object is to provide apparatus for the production of novelty loop yarns from continuous fibers wherein the fibers of the loop yarn can be made of differing diameters as compared to the fibers of the carrier yarn, and wherein the loops are filamentized to provide a novel product.

Other objects of this invention will appear in the following description and appended claims, reference being had to the accompanying drawings forming a part of this specification wherein like reference characters designate corresponding parts in the several views.

FIGURE 1 is a front elevation, partly sectioned, of apparatus for producing continuous fibers from heatsoftenable materials, such as glass;

FIGURE 2 is a side elevation of FIGURE 1, also partly sectioned;

FIGURE 3 is an elevation view of apparatus used for producing novel loop yarns directly from a forming operation for continuous fibers in accordance with the invention and packaging the so-produced, novel yarn;

FIGURE 4 is an elevation of a second embodiment of the invention for producing novel loop yarns directly from a continuous fiber forming operation and packaging the so-produced, novel yarn;

FIGURE 5 is an illustrative view of apparatus for producing novelty loop yarns from at least two previously produced separate fibrous strands;

FIGURE 6 is a side view of apparatus for application with apparatus of FIGURES 3 and 4 to apply constant tension to the strand fed to the pull wheels and thereby prevent overrun and looping at the guide wheels;

FIGURE 7 is an elevational view of apparatus and illustrating another method of filamentizing a loop yarn;

FIGURE 8 is still another view of apparatus used for filamentizing the loop yarns for use in the invention;

FIGURE 9 is a greatly enlarged perspective view f a loop yarn of the invention; and

FIGURE 10 is a view illustrating prior analogous, tightloop products.

Before explaining the present invention in detail, it is to be understood that the invention is not limited in its application to the details of construction and arrangement of parts illustrated in the accompanying drawings, since the invention is capable of other embodiments and of being practiced or carried out in various ways. Also, it is to be understood that the phraseology or terminology employed herein is for the purpose of description and not of limitation.

Briefly, the present invention relates to the production of novelty loop yarns wherein both a carrier yarn and the loop yarn are formed under conditions of constant tension in initial fiber production and yarn formation, thus assuring the production of fibers of uniform diameter in the finshed product; and the so-called over-run or loop strand is filamentized prior to combination in the final product yarn. This basic concept of the invention is applicable both to the production of a novel loop yarn directly from the forming operation, and also from previously formed strands, in a twisting operation, with various methods for filamentizing the loop yarn becoming a part of the invention.

The extended scope of invention also logically includes the product wherein the carrier strand is tensioned and the loop strand is filamentized, thus exhibiting a realistic wool-like product as regards feel and weaving characteristics, and to the method of production.

Although the invention will be illustrated relative to the production of glass fibers, it is to be understood that the invention is applicable to substantially any continuously producible filamentizable material.

By reference to FIGURES 1 and 2, a typical environmental background relating to the formation of continuous glass fibers from a body of molten glass will be briefly described.

Thus, as shown in these figures of the drawings, continuous glass fibers are formed utilizing a rn'ellerfeeder or bushing 12, heated as hereinafter described to provide a body of molten glass 14. Thus, the bushing 12 is provided with electrical terminals 16 at each end, FIGURE 2, to which electrical lines 18 and 20 are connected whereby electric current is passed through the bushing to heat the same by its own internal resistance. An insulating refractory 22 is provided around the bushing 12 to retain heat and thereby improve efficiencies.

Although not shown, a means for feeding glass marbles or powdered glass-forming materials, typified by a suitable chute or hopper is provided above the bushing 12.

Glass-forming materials are fed by gravity into the bushing 12 at a controlled rate. In the bushing 12, the glass-forming materials are converted into molten glass to provide the body 14 which is exuded downwardly from a plurality of apertures 24, formed in aligned array over the bottom of the bushing, as small molten streams 26. The streams 26 are attenuated into the fibers 10 by being pulled as will be hereinafter described, and the fibers 10 are passed into tangential contact with a sizing belt 28 operating over a roll 30 and a guide 32. The roll 30 is positioned within a container 34 that retains a body of liquid size 36, with the bottom portion of roll 30 being immersed in the liquid size; thus, as the belt 28 passes over the roll 30 it is wetted to transfer the size to the fibers 10 during their tangential passage over the belt at the guide point 32. A conduit 38 supplies fresh size to the container 34 and an exhaust conduit 40 recirculates the size to a central source for purification and enrichment to assure a fresh, clean supply.

A depending arm 42, attached to the container 34, supports a gathering guide 44 which takes the form of a small wheel having a V-shaped groove in the periphery and that is made of wear-resistant material such as graphite. The wheel form is desirably used in the guide 44, so that as wear develops, the wheel can be indexed to bring a new gathering surface into position for accurate fiber gatherings. This belt, wheel-guide arrangement is considered an advance in the art over the earlier used saturated wool gathering pads which, of course, needed replacement because of the cutting action of the fibers on the wood pad.

After the fibers 10 pick up a coating of size by contact with the wetted belt 28 at the point 32, they are converged into a strand 46 by the V-periphery of the gathering guide 44. The strand 46 is then passed downwardly to apparatus forming part of the present invention and wherein an attenuating force is provided, and a complete description of the apparatus of invention and method and product produced will now follow:

THE EMBODIMENT OF FIGURE 3 By reference to FIGURE 3, which represents a first embodiment of the invention, it should be noted that the strand 47 is designated a slow strand and that the strand 50 is designated a fast strand.

Now discussing strand 47 first, it will be noted that this strand proceeds downwardly to an idler roll 48, which has a braking mechanism attached thereto to be subsequently described with reference to FIGURE 6. The strand 47 half laps the idler roll 48 and thence proceeds vertically upwardly to a wheel puller 52, rotatably driven in the arrow 54 direction by mechanism such as a suitable electric motor, not shown. As the strand 47 laps the puller S2 to the point 56 it is tangentially thrown from the puller to a filamentizer 58, here exemplified as a tangential air blower.

Now referring to the fast strand 50, it will be noted that an adjustable speed idler wheel 60 is half lapped and that the strand then proceeds vertically upwardly to a second wheel puller 62 which it half laps and is tangentially thrown to the air blower 58 from the point 64.

Now it will be understood that the two

strands

47 and 50 are combined at the air blower 58, and it is at this point that the invention truly reflects itself.

Thus, strand 50 will be understood to be moving faster than the slow strand 47 and will thus be in a slack condition as compared to the slow strand within the air blower 58. Loop formation thus starts at this point and as the loops are formed, e. g., as the strand is slackened it will be understood that the action of the air of blower 58 tends to separate or filamentize the individual fibers 10 of the faster strand 50.

Incorporation of the fast and slow strands, the fast strand having been filamentized, is effected by substantially instantaneously at the point of filamentization imparting a twist to the two strands to interlock them and preserve the loop form produced by the fast strand.

For this purpose, the two strands are ballooned downwardly as at 66 to a winding mechanism designated 68, typically comprising a cap winder 70 operating over a rotating package 72. Rotating package 72 is suitably carried on a conventional textile yarn twist frame adapted for glass fiber processing, and it is to be understood that as the balloon 66 circumscribes the package 72, a desired number of twists or turns per inch is imparted to the combination strand 74. The twist is effective to retain the loop form of the fast strand 50 in the package 72.

Although the cap winder 70 forms no essential part of the present invention, it will nevertheless be described to provide full clarity of description for the reader. Thus, the cap winder 70 operates in conjunction with a motor 71 having a hollow shaft 71s supporting a collet 710 that carries a winding tube 721. Beneath the motor 71 is located a hydraulic cylinder 69 including a piston rod 69r, extending up through the hollow shaft 71s of motor 71. The piston rod 691 is pointed at the top end to receive cap 70, having an appropriate internal socket. The cap 70 does not rotate and accordingly the angularity cf the bottom edge controls lay of strand on the package 72. Movement of the piston rod 69r in an up and down manner provides .yarn traverse on the package 7 2.

This product may be used as is; however, as known in the art, the product will be wild, and if desired may be pliedwith another combination strand of like configuration to provide a balanced product.

Regarding the foregoing description, it is to be understood that the fast strand 50 moves at a higher linear speed than the slow strand to provide the loops indicated at 74 for the combined strand. Relative speeds in the range from 1.25 to 2X the speed of the slow strand can be induced into the fast strand to provide variations in loop lengths and bulk of the finished yarn 74, and these are not to be considered limiting on the invention. However, a ratio in the range of about 2 to 1 has been found to provide a very satisfactory final product.

As mentioned hereinbefore, it is an advantage of the present invention that during forming, all fibers are under constant tension assuring uniform diameters. One might well ask at this point if the strand 47 is pulled at a slower rate than strand 50, how can all fibers be of the same diameter? This is answered by adjustment of the size of the apertures 24 to produce molten streams commensurate with drawing speeds to have all fiber of uniform diameter if desired. However, a logical extension of the invention would include all apertures 24 of both bushings being of the same size so that all glass streams are of the same size and thus the fibers of the slow strand would be larger in diameter than the fibers of the fast strand. It is evident that some end products would advantageously employ such a combined yarn 74 including such differing diameter fibers in the two strands.

THE EMBODIMENT OF FIGURE 4 Reference to FIGURE 4 will indicate that essentially the same phenomenon or effect as produced in FIGURE 3 can be provided by using two individual bushings 12; or optionally a single bushing, split as known in the art, to produce slow and

fast strands

47 and 50. It will be noted in this embodiment that the

strands

47, 50 are run over two side-by-side idler-tension rolls 76 and thence passed to a stepped single wheel puller designated by the reference numeral 78, to produce the differential in speed between the

strands

47 and 50. It will be noted that the puller 78 has a section 80 of larger periphery and a section 82 of smaller periphery.

As previously described for the pullers of FIGURE 3, the strands are ejected from the periphery tangentially as at the point 84 and directed to the tangential air blower 58, so designated because of the same configuration as in FIGURE 3. Subsequent processing is as described in FIGURE 3, comprising ballooning as at 66 with downward movement to winding mechanism 68, characterized by a textile twisting frame utilizing a cap winder 70 and forming a package 72. The combined strand 74 with looped and carrier strand in combination is accordingly produced.

THE EMBODIMENT OF FIGURE 5 A logical extension of the concept of the present invention is illustrated in FIGURE 5 wherein packages 86 and 88, as from a conventional textile forming operation, are utilized as starting materials for processing in accordance with the invention.

Thus, for purposes of description, the strand 90 moving from the package 88 will be designated the slower or carrier strand that is moved downwardly to pull

rolls

91, 92 and thence to a guide eye 94. It will be noted that this is a slight departure from feeding both strands into the tangential air blower as shown in FIGURES 3 and 4; however, the same effect is provided. The slower strand in this embodiment and the foregoing embodiment would be prevented from filamentizing in the air blower 58 because of constant tension. It is the faster strand which is filamentized because of the slack developed therein in its faster running or overrunning compared to the slower strand.

Accordingly, the faster strand 96 is moved downwardly to pull

rolls

98, 100, thence to the tangential air blower 58, previously mentioned From the air blower 58, where the faster strand 96 is filamentized, the filamentized strand designated 102 moves to the guide eye 94 for incorporation with the slow strand 90. Briefly this includes a balloon as at 66 to the twister spindle 63 carrying a ring and traveler 104 as distinguished from the cap winder 70 of FIGURES 3 and 4 to form th combined strand 74 containing filamentized loops.

SUPPORTING ELEMENTAL DETAILS OF THE INVENTION The idler wheel brake In the description above regarding FIGURES 3 and 4 it was indicated that the

idler wheels

48, 60 and 76 were provided with suitable braking mechanism to prevent overrunning of the strands and malfunction due to looping wheel puller slippage and the like.

Accordingly, one suitable mechanism for providing an adjustable braking effect and thus a constant tension through the medium of

idler wheels

48, 60 and 76 is shown in FIGURE 6. This comprises a small centrifugal air blower including a housing 106 within which a vane wheel 108 is rotated on a shaft 110, common to the shaft of the

idler wheel

48, 60 or 76 of FIGURES 3 and 4. It will be noted that the housing 106 is provided with an inlet 112 and an outlet 114 and that in the outlet duct 114 therein is imposed an adjustable valve 116 to control air flow from the unit and thereby impose a variable load on the vane wheel 108. It will be understood that the larger amount of air pumped or the larger opening of the valve 116 gives a greater load and thus reduces speed, tending to impose a proper restraint upon one of the

guide wheels

48, 60, 76 and thereby effectively controls tension with a minimum expenditure for apparatus.

Due to the fluid nature of the air being pumped, it will be found that a certain degree of flexibility or tolerance is actually provided for each setting of the valve 116.

This element may be characterized broadly as a fluid brake.

THE AIR JET FILAMENTIZER As shown in FIGURE 7, one suitable filamentizer includes a plurality of gas directing nozzles 118, attached to the forward end of conduits 120. It will be noted that jets 122 are directed into colliding relation with one another as indicated by the blast zone 124 where the slack in the fast strand, typically designated 50, begins to develop and thus, the filaments or fibers 10 are blasted apart as indicated by the reference numeral 124. The filamentized strand 126 is thereafter directed to a guide eye 94 for combination with a slower, tensioned strand, characterized by the

reference numerals

47, 90. As indicated, from the guide eye 94, the filamentized strand 126 and the

taut strand

47, 90, proceed to a twister, thereby forming an integrated, coherent product.

THE SLACK ROLL FILAMENTIZER Referring to FIGURE 8, there is shown an alternate method and apparatus for filamentizing within the scope of invention. Thus, a high speed or fast strand 50 is run between a first pair of slack inducing rolls 128, in peripheral contact and driven in the arrow 130 direction. These are spaced from from a second pair of slack in ducing rolls 132 with the yarn length between the rolls being adjusted to be greater than the length between the axes of the

rolls

128 and 132.

It may be found because of the previous set to the binder applied to the fibers in forming, that an optional gas jet 134 will be necessary to provide optimum filamentizing in the zone designated 136. In any event, the strand produced is filamentized as indicated at 126, in a manner analogous to the showing of FIGURE 7. The filamentized strand then moves to a guide eye 94 for combination with a slow strand 47, and thence to a subjacent twister, as exemplified by the arrow 95.

THE PRODUCT OF INVENTION The product of the present invention is illustrated more clearly in the enlarged view of FIGURE 9 wherein the tensioned multi-fiber or monofilament carrier strand is designated 47, 90 and the

loop strand

50, 96. Note the exposed end of the carrier strand and the integrity illustrated in the fibers. Note in contrast the filamentized configuration of the individual fibers at the free or exposed bight 138 of the loop 137, wherein the individual fibers 10 are clearly exposed and separated from one another.

The distinguishable and contrasting prior art product is illustrated in FIGURE 10. Note the tight configuration of the loops indicated *by the reference numeral 140.

PROCESS SUMMATION The process of invention essentially resides in the following aspects:

(1) Providing a first linearly moving carrier strand;

(2) Providing a second linearly moving multi-fiber loop strand at a rate greater than the rate of 1, to provide loop formation;

(3) Fiberizing the second strand, at some point in its hi tory;

(4) Combining the two strands at the lineal rate of travel of the first or slower strand to provide loops along the length of the carrier; and

(5) At least relatively fixing the configuration of the GENERAL COMMENTS AND EXTENDED SCOPE As regards production of the product of invention in accordance with the forming methods of FIGURES 3 and 4, it will be understood that the size applied at the point 44 will still be Wet upon entrance of the slow strand into the tangential air blower or filamentizer 58. At this point it will of course be understood that at least part of the moisture will be ejected from the fibers and thus impart a set to the solids of the size and binder which remains, and thus tend to give the filamentized fibers a set in the filamentized condition.

This is a definitely unexpected result over the prior art which, as far as the present inventors are knowledgeable, does not even contemplate the filamentizing aspect of the present invention.

Thus, as the size is partially dried, the filamentized fibers stay blasted open. The enhances the woolly characteristic or wool-like feel of the product as distinguished from the prior art analogous materials, which as pointed out above, are of tight-looped configurations.

Processing speeds according to the present invention are substantially flexible, being variable in the range from about 300 feet per minute to as high as 10,000 to 12,000 feet per minute. At these higher speeds, of course, the braking or tensioning effect provided by the blower brake of FIGURE 6 becomes especially valuable in contributing to the efficiency of the processing of the invention.

It should be pointed out that the present invention is distinguishable from the known prior art by the use of a constant tension applied to the individual fibers or filaments during their formation, as contrasted to the prior art where slack is developed to give a crinkled type fiber in the carried yarn, which of course means that such crinkled fibers are of erratic varying diameters and are of generally enlarged diameter. The invention is also distinguishable from a plain looped fiber or boucle yarn on a tensioned carrier in that in the prior art there was no filamentization of the individual fibers of the loop yarn as has been discovered in accordance with the present invention.

It is also to be understood in view of the foregoing that the present invention contemplates processing speeds tremendously in excess of those contemplated in the prior art, typical prior figures as regards production of fibers from regenerated cellulose solutions on the order of 1,000 meters per minute maximum for orifices of diameter 0.075 mm. and 0.10 mm. Actually, the prior art states that it is usually preferable that the linear extrusion rate employed for a given spinning solution using orifices of a given diameter should not greatly exceed the minimum rate at which crinkled filaments are formed under under these conditions, since considerably higher rates not only involve the use of spinning pressures that may be inconveniently high, but may also give a less satisfactory product.

The present invention is also cleariy distinguishable from regenerated cellulose made into nubby yarns wherein a pulsating motion is imparted to the viscose filamentforming solution prior to its passage through the spinning cell, or the filaments, after formation, may be drawn at abruptly changing linear speeds. As pointed out before, filament formation is characterized in accordance with the present invention by constant tension being applied to the filaments for attenuation purposes. Thus, no pulsating motion to the forming mass or to the strands or fibers is utilized; contributing substantially to improved pro-cessing and higher rates of manufacture.

While the foregoing discussion has related to both strands being of the same material, to-wit, made up of a plurality of continuous glass fibers in side-by-side associated or adhered relationship and oriented in a common axial direction, the broad scope of invention would include two different types of strands. That is, the carrier strand in the ultimate yarn can be of soluble material that would dissolve or integrate with a matrix material in which the end product is incorporated, as in a plastic laminate or the like. In another sense, the carrier strand can be stated as a thermoplastic material of a lower melting point than the loop strand, and made of the same material forming the body of the matrix impregnated in the woven material. Thus, the carrier strand, for example, could be made up of acrylic fibers and these would dissolve in an impregnating acrylic resin, forming a panel in which the loop yarn is incorporated as a reinforcement.

Also, the carrier strand could be made of a readily fracturable material, such perhaps as silica fibers that would be sufficiently strong to permit weaving, but would break into smaller lengths during a drafting or drawing of the woven product to conform to shapes as in resin molding operations, such as matched metal molding processes. The broken lengths could be of quartz or glass fibers of sufiiciently small yarn diameter that the breakage would occur only during the drawing but not during the weaving operation.

Also, while the foregoing invention has related to glass fibers, it is to be understood that heat-softenable materials broadly capable of attenuation or formation into fine fibers are contemplated within the broad scope of invention. The tension aspect is also to be understood to encompass regeneratable materials such as viscose, at constant velocity and subsequent blasting.

The invention would also encompass the processing of staple fiber strands.

The combination of the fast strand with the slow strand at the filamentizing blower or guide ring by the present invention can be described by reference to a single point on the fast strand. Thus, when this point is approaching the slow strand, it is moving at a constant forward lineal velocity. However, when it actually wraps onto the carrier or slow strand, the point of contact as distinguished from a part of the loop, moves forward and stops and the loop points continue to move forming the loop and then another point contact abruptly stops. It might be said in describing this phenomenon that a pulsating motion is imparted to some points on the strand as distinguished from others as the overfed strand is moved into the final bulky yarn; thus at least some points are characterized by abruptly changing linear speeds.

ADVANTAGES OF THE INVENTION Firstly, it is to be understood that a novel, filamentized, loop yarn is manufactured in accordance with the present invention, thus providing a substantial contribution to the art of manufacture in the utilization of heat-softenable materials, producible as by attenuation from a molten body of the same.

A further advantage of the invention resides in the novel processing contribution to the prior art in the form of application of uniform tension to the fibers during manufacture and the subsequent overrunning of one of the strands so produced with filamentization before or substantially at the point of combination with a slower running, tensioned carrier strand.

The present invention also provides a distinct advantage to the art by the contribution of novel apparatus for producing the novel product. Thus, the use of a fluid brake is contemplated to prevent looping at the idler wheel and, in accordance with the invention, the apparatus provides for the formation of the novel product directly from virgin fiber production. Thus, intermediate handling, labor and processing are omitted, contributing to greater economy of production as contrasted to the prior art methods where a twister prepares loop yarns by feeding one yarn end excessively so that when the binder yarn is applied, loops appear at intervals along the length of the binder yarn. This presumes of course prior strand formation, the product being characterized in FIGURE 10 of the drawings.

We claim:

1. In a looped yarn,

a carrier strand of generally smooth axial alignment and direction and orientation,

a looped strand having consecutive loops curled around said carrier strand along the length thereof,

and the fibers of said looped strand being filamentized at least in the bight portions of the loops.

2. In a looped yarn made from a carrier strand and a looped strand,

each strand being comprised of a plurality of continuous glass fibers associated in generally parallel, axially aligned array,

said carrier strand being coherent of generally smooth axial alignment,

said looped strand having consecutive loops curled around said carrier strand along the length thereof,

the fibers of said looped strand being at least partially filamentized at least in the free bight portions of the loops,

and said composite yarn having twists along the length thereof, retaining said looped strand in positive association With said carrier strand.

3. In a looped yarn,

a coherent carrier strand comprised of a plurality of fibers of heat-softenable material and associated in generally parallel, axial alignment,

said looped strand comprising a plurality of fibers of heat-softenable material,

4. In a looped yarn,

a coherent carrier strand comprising a plurality of fibers of heat-softenable synthetic resin bonded together in generally parallel axial alignment, and said carrier strand being of generally smooth axial alignment and direction and orientation,

a looped strand having consecutive loops curled around said carrier strand along the length of said carrier strand,

said looped strand being comprised of a plurality of continuous siliceous fibers associated in generally parallel axial alignment,

5. In a looped yarn,

a coherent carrier strand comprised of a plurality of siliceous fibers bonded together in generally parallel axial alignment, and said carrier strand being of generally smooth axial alignment and direction and orientation,

said looped strand comprising a plurality of nonsiliceous fibers associated in generally parallel axial alignment,

the fibers of the looped strand being filamentized at least in the bight portions of the loops,

and said composite yarn having twists along its length retaining the loops in relatively fixed relation along the length of the carrier strand.

6. In a looped yarn,

a coherent carrier strand comprised of a plurality of fibers bonded together in generally parallel axial alignment, and said carrier strand being of generally smooth axial alignment and direction and orientation,

a looped strand forming loops having consecutive loops curled around said carrier strand and extending along the length of said carrier strand,

said looped strand also comprising a plurality of fibers associated in generally parallel axial alignment,

the fibers of said loops being filamentized at least in the bight portions of the loops,

and a dry 'binder retaining said loops in relatively fixed relation along the length of said carrier strand.

7. In a looped yarn,

a coherent monofilament carrier strand of generally smooth axial alignment and direction and orientation,

a looped strand having consecutive loops curled around said carrier strand and extending along the length of said carrier strand,

said looped strand comprising a plurality of fibers associated in generally parallel axial alignment,

said fibers ofsaid loops being filamentized at least in the bight portions of said loops,

and said looped strand being curled around said carrier strand along the length thereof.

8. In a looped yarn,

a carrier strand of tensioned, generally smooth axial alignment and direction and orientation,

the fibers of said looped strand being filamentized at least in the bight portions of the loops,

and a dry binder on said filamentized fibers, holding said filamentized fibers in such condition.

9. In a looped yarn,

a coherent carrier strand comprising a plurality of fibers held together in generally parallel, axial alignment, and said carrier strand being of generally smooth axial alignment and direction and orientation,

a looped strand having loops curled around said carrier strand along the length of said carrier strand,

said looped strand also comprising a plurality of fibers associated in generally parallel, axial alignment,

said loops being in relatively fixed relation along the length of said carrier strand,

and a dry binder holding said filamentized fibers in separated condition.

References Cited UNITED STATES PATENTS 2,807,864 10/1957 Head 28-75 2,852,906 9/1958 Breen 57-34 2,901,884 9/1959 Weinberger et al. 57-144 3,026,597 3/1962 Swaney 57-34 X 3,097,412 7/1963 Becher 57-34 X 3,103,731 9/1963 Salyer et al. 57-34 X 3,118,213 l/1964 Benson 57-34 X 3,019,592 2/1962 Gould et a1. 57-144 3,041,812 7/1962 Marshall 57-6 3,082,591 3/1963 Marshall 57-6 FOREIGN PATENTS 828,641 2/ 1960 Great Britain. 861,327 2/1961 Great Britain.

JOHN PETRAKES, Primary Examiner.

Claims

1. IN A LOOPED YARN, A CARRIER STRAND OF GENERALLY SMOOTH AXIAL ALIGNMENT AND DIRECTION AND ORIENTATION, A LOOPED STRAND HAVING CONSECUTIVE LOOPS CURLED AROUND SAID CARRIER STRAND ALONG THE LENGTH THEREOF, AND THE FIBERS OF SAID LOOPED STRAND BEING FILAMENTIZED AT LEAST IN THE BIGHT PORTIONS OF THE LOOPS.