US3255508A - Apparatus for crimping textile yarn - Google Patents

Apparatus for crimping textile yarn Download PDF

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US3255508A
US3255508A US405008A US40500864A US3255508A US 3255508 A US3255508 A US 3255508A US 405008 A US405008 A US 405008A US 40500864 A US40500864 A US 40500864A US 3255508 A US3255508 A US 3255508A
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yarn
screen
nozzle
barrier
speed
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US405008A
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Weiss Ernst
Rudolf A Prokesch
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EIDP Inc
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EI Du Pont de Nemours and Co
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    • DTEXTILES; PAPER
    • D02YARNS; MECHANICAL FINISHING OF YARNS OR ROPES; WARPING OR BEAMING
    • D02GCRIMPING OR CURLING FIBRES, FILAMENTS, THREADS, OR YARNS; YARNS OR THREADS
    • D02G1/00Producing crimped or curled fibres, filaments, yarns, or threads, giving them latent characteristics
    • D02G1/16Producing crimped or curled fibres, filaments, yarns, or threads, giving them latent characteristics using jets or streams of turbulent gases, e.g. air, steam

Definitions

  • This invention relates to a method of tex-turing or crimping textile yarns, and to a novel apparatus for carrying out the process.
  • crimped continuous filament synthetic yarns composed of materials such as the polyamides, for example, polyhexamethyleneadipamide and polymerizates of E-caprolactam
  • this invention is also applicable to polyester yarns for example, polyethyleneglycol terephthalate as well as polyvinyl base yarns such as polyacrylonitrile. It is also applicable to the crimping or texturing of cellulose derivative yarns, for instance, cellulose acetate, and also to the crimping of natural silk.
  • Yarns of the above materials may be composed of either continuous multifilaments or staple fibers.
  • the process of the present invention is particularly advantageous when compared with prior art crimping techniques because it permits crimping at comparatively much higher yarn velocities than has been possible heretofore, and yet the crimped product so produced is at least as uniform and voluminous as yarns which have been crimped by other slower and less economical processes.
  • a normal multifilament textile yarn having no twist or a twist of between zero and about 300 turns per meter is continuously plastified and propelled by means of a high speed laminar stream of fluid directly against a barrier having a surface which is either so positioned as to deflect the fluid or of a character such as to permit free passage of the fluid.
  • the fluid is substantially immediately diverted from the barrier in order to prevent the formation of turbulent streams on the surface of the barrier.
  • the barrier against which the yarn impinges is continuously moved so that a fresh surface is always presented, and the yarn is permitted to remain temporarily thereon.
  • the yarn is then continuously removed from the surface by a takeup device, set or cooled and wound up.
  • the starting multifilament yarn is a normal textile yarn which has no twist or is twisted only to the extent necessary to retain the individual filaments of the yarn in a reasonably closely packed bundle.
  • the filaments are mechanically deformed whereby the fiber bundle is opened up.
  • the thus deformed yarns are permitted to remain temporarily on the surface of the barrier.
  • Substantially 'complete setting or hardening is effected as'by natural or forced cooling before any substantial tension is applied to the crimped product.
  • the fluid medium which propels the yarn against the barrier be diverted as soon as possible after impingement of an adjacent incremental length of yarn in order that fluid currents not disturb the yarn on the surface of the barrier.
  • a screen or sieve barrier which offers essentially no resistance to the flowing fluid.
  • a screen another surface which is permeable to the fluid may be employed, for example, a clay filter or a hard foam substance of synthetic resin, the surface of which is characterized by a Fee plurality of recesses or depressions.
  • the impingement surface may be a fluid impermeable mate rial, for example, a corrugated, textured or granular surface, in which case the surface is positioned at a relatively steep angle to the axis of the traveling yarn, thereby readily permitting angular deflection of the flowing fluid.
  • the barrier surface is described as irregular since the elements of the surface are not coplanar or the surface is not continuous.
  • a sieve or screen in the shape of a drum is the preferred barrier, although the screen may present a plane surface at the point of yarn impact.
  • the barrier screen is preferably of a size between 25 and 200 mesh. Throughout this application screen sizes are given in terms of US. Sieve mesh. k
  • the yarn treated is composed of a thermoplastic material which can be rendered su-fficiently plastic simply by the application of heat.
  • the flowing'medium is compressed air at an elevated temperature which not only propels the yarn but also is in contact with the yarn for a sufiicient period of time to effect plastification.
  • gases may be employed, including the vapors of a normal swelling agent for the yarn being crimped.
  • the flowing medium may be a liquid, for example, either water at elevated temperature or a solution of a swelling agent for the particular yarn. Heated air or steam are the preferred fluids because the apparatus can be considerably simpler and the flowing fluid will present no collecting and disposal pro lems. It is also possible to plastify the yarn simply by passing it through a swelling liquid. In such cases compressed air at ambient temperatures may be employed as the yarn impelling fluid.
  • FIG. 1 is a sectional view of an embodiment of the apparatus of the present invention
  • FIG. 2 is an enlarged sectional view of a portion ofthe nozzle end of the yarufeeding and heating device of FIG. 1;
  • FIG. 3 is an enlarged plan view of a portion of a barrier screen with a length of yarn thereon;
  • FIG. 4 is a sectional elevation taken on the line 44 of FIG. 3;
  • FIG. 5 is a view of a length of multifilament yarn which has ben textured in accordance with the present invention.
  • FIG. 6 is a sectional view of the yarn feeding tube and nozzle of another embodiment of the present invention.
  • FIG. 7 is a schematic representation of a portion of the apparatus of the present invention illustrating gas conveying, heating and collecting means
  • FIG. 8 is a schematic view illustrating a different relationship between the nozzle and the barrier
  • FIG. 9 is another schematic view illustrating the use of a continuous plane barrier
  • FIG. 10 is a perspective view illustrating another plane barrier and the relationship of the nozzle thereto;
  • FIG. 11 is a schematic elevation of a complete yarn crimping apparatus in accordance with the present invention.
  • FIG. 12 is a sectional elevation of thefluid heating means, yarn feeding tube and nozzle of the apparatus of FIG. 11;
  • FIG. 13 is an enlarged detail of the lower end of the yarn feeding tube and nozzle of the apparatus of FIG. 12, and
  • FIG. 14 is a greatly enlarged detail of the nozzle of FIGS. 12 and 13.
  • FIG. 1 wherein there is illustrated one of the simplest embodiments of the pres ent invention.
  • a thermoplastic yarn 11 is fed axially by a pair of feeder rollers 12 and 12a to a yarn feeding tube 21 which is jacketed with an electrical resistance coil 14.
  • the feeding tube and heating coil 14 are surrounded by an outer jacket 13 which is spaced from the heater to provide an annular passageway 13a (FIG. 2).
  • An opening 15 is provided for introduction of air under pressure which flows along substantially the complete length of the heating element and then comes in contact with the yarn 11 just outside a labyrinth seal 16 at the feed end of the outer jacket.
  • the air then passes axially in a laminar stream through the feeding tube 21 and propels the yarn 11 toward the nozzle end 17.
  • the nozzle 18 (FIG. 2) is of the De Laval injector type, and is positioned in close proximity to a wire mesh screen 19, which is mounted on a rotating drum 20.
  • the yarn is conveyed axially through the feeding tube and nozzle at substantially the same velocity with which it is delivered by the feeder rolls 12 and 12a and impinges upon the moving surface of screen 19 as shown in FIG. 2.
  • the yarn is heated to a plastic condition.
  • the plastified yarn hits the screen it is deformed i.e. crimped due to the impact on the hard wires of the screen, whereas the air stream passes through the screen.
  • FIGS. 3 and 4 it is seen that the yarn on the screen is quite voluminous due to its crimped filaments.
  • the sieve 19 is constantly rotated in order to present a fresh surface to the traveling yarn, but rotation is at a substantially lower linear velocity than that of the feed rollers 12 and 12a since the yarn is appreciably reduced in length by reason of its deformation on the screen. While it is difficult to prescribe a definitive ratio of the linear velocity of the feed rollers to the velocity of the screen it is reasonable to say that the screen is moved at a velocity between about and 75% of that of the input or feed rollers.
  • a pair of takeup rollers 22 and 22a are so positioned with respect to the screen 19 as to enable a temporary retention of the yarn on the impact surface.
  • the deformed yarn remains on the screen from the point of impact to a point 23 on the drum 20.
  • the takeup rollers 22 and 22a are so operated as to remove the yarn from the screen at a linear speed slightly greater than the speed at which the screen is moving.
  • the takeup device operates at a linear speed between about 50 and 90% of the speed of the feed rollers.
  • the ratio of linear speeds of the feed rollers, moving screen and takeup rollers is about 100:55270.
  • FIG. 6 Another yarn feeding member is illustrated in FIG. 6 wherein the feeding tube 21 is provided with a spaced jacket 24 which is adapted as at 25 for introduction of a hot fluid medium, for example air under pressure.
  • the lower end of tube 21 and jacket 24 are shaped as at 26 and 27 respectively, to provide a modified injector nozzle which is positioned adjacent the barrier, for example, screen 19.
  • the air or other flowing medium is exteriorly heated, and after passage of substantial quantities of hot gas the feeding tube 21 becomes hot and acts as a radiant heater for the yarn.
  • the direct contact with the hot gas at the nozzle is generally sufficient to plastify the yarn.
  • the barrier screen is preferably in the shape of a drum and the yarn is preferably directed at the outer surface of said drum as shown in FIGS. 1 and 7, the yarn may be impinged upon the inner side of a drum-shaped screen 19b, as shown in FIG. 8.
  • the entire yarn feeding member is positioned inside of the screen drum 20a.
  • the yarn may also be impinged upon a plane irregular surface, for example, a continuous length or belt of screen material 19c (FIG. 9) moving about a pair of rollers 36, 37.
  • a plane irregular surface for example, a continuous length or belt of screen material 19c (FIG. 9) moving about a pair of rollers 36, 37.
  • the yarn may be impinged upon a circular plane irregular impact surface such as screen 19d in FIG. 10, which'is suitably mounted on a rotating shaft 38.
  • the time of residence of the yarn 11 On the screen may be controlled not only by the speed of rotation of the screen but also by adjusting the radial distance between the center of the screen and the point of impingement.
  • FIGS. 11-14 is a typical machine in accordance with the present invention for crimping a single yarn.
  • the apparatus is vertically arranged with the yarn 11 being drawn from one of the pirns 41. Two such pirns are shown, and the one on the right is a spare pirn.
  • the yarn 11 is drawn from the pirn by feed rollers 12, 12a, in which pair roll 12 is a driven pressure roll, through a yarn brake mechanism illustrated generally at 42, and thence by suitable guide rollers through a trough or other liquid container 43 where the yarn is moistened.
  • the yarn then passes into the feeding tube, not shown, where it is contacted with heated air, for example, and discharged through nozzle end 17 in the usual manner.
  • the feeding tube, heater and nozzle are enclosed by a cover member indicated generally at 44;
  • the yarn impinges upon screen drum 20 which is rotated by means of a drive indicated at 46. It is then removed from the screen under slight tension exerted by a driven takeup roller 47.
  • the crimped yarn passes in contact with a pivotal guide 51 which equalizes tension in the yarn and thence in contact with a further guide system 52.
  • the yarn is finally wound under slight tension onto a spool or bobbin 53.
  • the yarn feeding tube 21 is provided at its lower exit end with a yarn heating and nozzle member indicated generally at 54. Air under pressure from a source not shown, is conveyed through pipe 55, to opening 57 in member 54. The air is heated by a ceramic insulated electric heating element 56 whichsurrounds the pipe.
  • member 54 consists of an upper hollow block 58 which is rigidly secured to the machine frame 59.
  • Block 58 is so constructed as to provide an annular manifold 61 intermediate its inner and outer concentric walls, and its outer wall is bored as at 57 to provide access from pressurize air line 55 to the manifold.
  • the inner wall of block 58 is threaded as at 62 to receive a nozzle block 63 which is axially bored and counterbored as shown and the counterbore is threaded as at 73.
  • lower end 70a of the counterbore is tapered as at 66 (FIG. 14) into bore 70.
  • the nozzle block 63 is also bored as at 67 to permit access from the manifold 61 to the lower end 70a of the counter-bore.
  • a tube 68 is positioned in the bore 70 by a forced or friction fit, and the upper end of the tube 68 is bored or otherwise machined to produce a taper 71, which tapered portion serves as an element of the injection nozzle.
  • the wall of the lower end of feeding tube 21 is tapered as shown at 74 and serves as another element of the injector.
  • the tapered portions of tubes 21 and 68 which come in contact with the air stream are highly polished.
  • An elongated hollow bolt 72 is secured by a friction fit about tube 21 and is threaded into nozzle block 63. It will be seen that the lower end of bolt 72 is spaced from the tapered end of tube 21, and also that the lower end of counterbore 70a is not threaded. When the bolt 72 is in position in the block its lower end serves as the upper wall of an axial chamber 64 which communicates with bore 67.
  • a spacing sleeve 75 having a flanged head 78, is positioned about hollow bolt 72 and is free to move axially relative thereto.
  • the lower end of sleeve 75 is provided with lock points indicated generally at 76 whichengage suitable recesses in the upper surface of the nozzle block 63.
  • a lock nut 77 is positioned on the bolt 72 just above the head 78 of the spacer sleeve. When the lock nut is tightened all parts are rigidly held in the position shown.
  • the nozzle is adjusted as indicated by the dotted lines 79 in FIG. 13 by backing off the lock nut and screwing down or backing off the hollow bolt, thus inserting or withdrawing the tapered end of tube 21, after which the lock nut is reset.
  • heated air enters the manifold 61 and passes into chamber 64 where it heats tube 21 and the other elements of the heating and nozzle member 54, and passes thence through the nozzle and into tube 68.
  • the yarn is easily plastified in passing through member 54 and by its direct contact with the heated air.
  • the air passes through chamber 64 and tube 68 in a laminar stream and any substantial formation of turbulant air streams is prevented.
  • Example 1 A 210 denier, 34 filament nylon yarn having a twist of 80 turns per meter was uniformly moistened with water and fed to the apparatus of FIG. 1 at a speed of 93.5 meters per minute, and propelled through the nozzle by a stream of air at 3 atmospheres absolute pressure and 270 C.
  • the yarn in plastic condition as a result of its passage through the heating element and contact with the heated air was directed against a drum-shaped rotating70 mesh wire screen and removed from the screen at a speed of 69 meters per minute after which it was conveyed to a winding apparatus.
  • the resulting crimped yarn was voluminous and had a crimp contraction of 19%.
  • Example 2 The nylon yarn of Example 1 was uniformly impregnated with a 1% aqueous solution of phenol and then impinged at a speed of 100 meters per minute with the aid of air at 3.5 atmospheres'absolute pressure and 200 C. against a rotating 100 mesh wire screen. The yarn was removed from the screen at a speed of 70 meters per minute and wound on a bobbin. The crimped voluminous yarn obtained had a crimp contraction of 9.5%
  • Example 3 A 140 denier, 68 filament nylon yarn having a twist of 20 turns per meter was propelled by air at 3 atmospheres absolute pressure and 265 C. at a speed of meters per minute against a. continuously rotating mesh wire screen as shown in FIG. 9. The yarn was removed from the screen at a speed of 70 meters per minute and Wound on a bobbin. Two such yarns were plied together with 100 turns per meter in the S direction and the finished crimped voluminous yarn has a crimp contraction of 9.5%.
  • Example 4 A slightly twisted 90 denier, 30 filament yarn of a po-' A 100 denier, 48 filament polyethyle'neglycol .terephthalate yarn having 30 turns per meter was uniformly impregnated with a 2% aqueous solution of phenol and processed as set forth in Example 2. The crimped voluminous yarn so produced had a crimp contraction of 4.7%. 5
  • Example 6 A 100 denier, 36 filament polyacrylonitrile yarn was passed through an injector nozzle at a yam speed of 64 meters per minute. Compressed air at 280 C. plastified and propelled the yarn against a round rotating mesh wire screen as illustrated in FIG. 10. The yarn was removed from the rotating screen at a speed of 58 meters per minute, cooled in air and subsequently wound onto a bobbin. The crimped voluminous yarn so produced had a satisfactory crimp contraction.
  • Example 7 A slightly twisted 200 denier, 33 filament cellulose acetate yarn made by spinning secondary acetate, was impregnated with a liquid mixture consisting of one part by volume of acetone alcohol and 99 parts by volume of water. It was then fed through an injector nozzle in accordance with the present invention at a speed of 65 meters per minute. In the nozzle it was plastified with compressed air at 265 C., and impinged directly upon a rotating porous clay cylinder which easily let the air pass through it. The resulting deformed yarn was removed from the olay'cylinder at a speed of about 59 meters per minute. The crimped, voluminous yarn was cooled in air and wound up. It had a satisfactory crimp contraction.
  • Example 8 A slightly twisted thread of 88 denier degummed natural silk was uniformly moistened with water and then passed through an injector nozzle at a speed of 64 meters per minute. to the nozzle and propelled the yarn against a rotating mesh wire screen drum. The yarn was subsequently removed from the drum at a speed of 52 meters per minute, cooled and wound on a bobbin. The crimped yarn so produced was voluminous and had a crimp contraction which was entirely satisfactory.
  • Crimp contraction is defined as the contraction of the yarn which results when the crimp is completely developed by wetting. This characteristic is determined and measured as follows:
  • An eight yard length of textured yarn is removed from each of five bobbins or cones and each length is wound onto a circular reeling device having a circumference of one yard, under sufiicient tension to cause the yarn to lie flat, e.g. about 0.1 g./den ier.
  • the yarn is then re moved from the reeling device in a skein which is eighteen Compressed air at 360 C. was introduced inches long and consists of sixteen lengths of yarn.
  • Each of the five skeins so formed is treated for minutes in distilled water at 6070 C. in a tensionless condition. It is then removed from the water and dried without tensron.
  • Each skein is then completely wet out by immersion for 30 seconds in water at 60 C. containing either 2 g./liter Santomerse No. 1 Flake (Monsanto Chemical Co.) or the same quantity of Perminal (Imperial Chemical Industries, Ltd.).
  • the skein is then hung on a hook in the wet state and loaded with 0.2 g./denier (e.g. 100/2 denier yarn with 640 g.). Care is taken to be sure that the skein hangs flat.
  • Percent crimp contraction 100- 1002b/ Ea) where and deform the yarn, the stream being diverted from the yarn at the barrier screen and the yarn being set on the screen while free from fluid disturbance, feed means for continuously forwarding the yarn into said nozzle, and takeup means for removing the yarn from the barrier screen at a speed between about and of the forwarding speed of the feed means.

Description

June 14, 1966 E. WEISS ETAL APPARATUS FOR CRIMPING TEXTILE YARN 4 Sheets-Sheet 1 Original Filed June 2, 1959 M & m m 1 w T L: m m H V a m F mwcm r x K i w N E D M [U am E M V. B l IV D 0? N N 1a? 0 h @0 i, w a 5 V////////// $vv-uw-vwvvvywmW June 14, 1966 E. WEISS ETAL APPARATUS FOR CRIMPING TEXTILE YARN 4 Sheets-Sheet 2 Original Filed June 2, 1959 IN V EN TOR-9. EPA/Jr I l 2:153 BY EuaoLr Pea/rs: cH. WM -9 ATTOIPIVEK).
June 14, 1966 E. w|-:|ss ETAL APPARATUS FOR CRIMPING TEXTILE YARN m s 7 HQ m a m m m s c m s i IEQ & 4
H54 T1 N0 C HA MEEE? Original Filed June 2, 1959 June 14, 1966 E. WEISS ETAL APPARATUS FOR CRIMPING TEXTILE YARN 4 Sheets-Sheet L IN V EN TORS. Ee/vsr WEISS. By EUDOLFHPOKESCI'I.
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w m o I United States Patent 3,255,508 APPARATUS FER CRIMPING TEXTILE YARN Ernst Weiss and Rudolf A. Prolresch, Wattwil, Switzerland, assignors, by mesne assignments, to E. I. du Pont de Nemours and Company, Wilmington, Del., a corporation of Delaware Original application June 2, 1959, Ser. No. 817,569, now Patent No. 3,156,028, dated Nov. 10, 1964. Divided and this application Oct. 8, 1954, Ser. No. 405,008, Claims. (Cl. 28-4) This is a division of our application Serial No. 817,569 filed June 2, 1959, and now US. Patent No. 3,156,028.
This invention relates to a method of tex-turing or crimping textile yarns, and to a novel apparatus for carrying out the process.
While directed primarily to the production of crimped continuous filament synthetic yarns composed of materials such as the polyamides, for example, polyhexamethyleneadipamide and polymerizates of E-caprolactam, this invention is also applicable to polyester yarns for example, polyethyleneglycol terephthalate as well as polyvinyl base yarns such as polyacrylonitrile. It is also applicable to the crimping or texturing of cellulose derivative yarns, for instance, cellulose acetate, and also to the crimping of natural silk. Yarns of the above materialsmay be composed of either continuous multifilaments or staple fibers.
The process of the present invention is particularly advantageous when compared with prior art crimping techniques because it permits crimping at comparatively much higher yarn velocities than has been possible heretofore, and yet the crimped product so produced is at least as uniform and voluminous as yarns which have been crimped by other slower and less economical processes.
In the present process a normal multifilament textile yarn, having no twist or a twist of between zero and about 300 turns per meter is continuously plastified and propelled by means of a high speed laminar stream of fluid directly against a barrier having a surface which is either so positioned as to deflect the fluid or of a character such as to permit free passage of the fluid. In either event, the fluid is substantially immediately diverted from the barrier in order to prevent the formation of turbulent streams on the surface of the barrier. The barrier against which the yarn impinges is continuously moved so that a fresh surface is always presented, and the yarn is permitted to remain temporarily thereon. The yarn is then continuously removed from the surface by a takeup device, set or cooled and wound up.
As noted above the starting multifilament yarn is a normal textile yarn which has no twist or is twisted only to the extent necessary to retain the individual filaments of the yarn in a reasonably closely packed bundle. By reason of the action of the fluid medium, particularly, at the point of impingement of the yarn against the barrier, the filaments are mechanically deformed whereby the fiber bundle is opened up. The thus deformed yarns are permitted to remain temporarily on the surface of the barrier. Substantially 'complete setting or hardening is effected as'by natural or forced cooling before any substantial tension is applied to the crimped product.
It is important to the present process that the fluid medium which propels the yarn against the barrier be diverted as soon as possible after impingement of an adjacent incremental length of yarn in order that fluid currents not disturb the yarn on the surface of the barrier. This is preferably accomplished by the use of a screen or sieve barrier, which offers essentially no resistance to the flowing fluid. Instead of a screen another surface which is permeable to the fluid may be employed, for example, a clay filter or a hard foam substance of synthetic resin, the surface of which is characterized by a Fee plurality of recesses or depressions. Alternatively, the impingement surface may be a fluid impermeable mate rial, for example, a corrugated, textured or granular surface, in which case the surface is positioned at a relatively steep angle to the axis of the traveling yarn, thereby readily permitting angular deflection of the flowing fluid. Throughout the specification and appended claims the barrier surface is described as irregular since the elements of the surface are not coplanar or the surface is not continuous. A sieve or screen in the shape of a drum is the preferred barrier, although the screen may present a plane surface at the point of yarn impact. The barrier screen is preferably of a size between 25 and 200 mesh. Throughout this application screen sizes are given in terms of US. Sieve mesh. k
' In the present process it is essential that the yarn be plasti-fied prior to impingement upon the surface of the barrier, that is to say, the yarn is rendered sufiiciently plastic that it will be easily deformed as the result of its impact inertia and the compressive force of the fluid stream. In most instances the yarn treated is composed of a thermoplastic material which can be rendered su-fficiently plastic simply by the application of heat. For example, in a preferred embodiment of the present invention the flowing'medium is compressed air at an elevated temperature which not only propels the yarn but also is in contact with the yarn for a sufiicient period of time to effect plastification. However, other gases may be employed, including the vapors of a normal swelling agent for the yarn being crimped. If desired, the flowing medium may be a liquid, for example, either water at elevated temperature or a solution of a swelling agent for the particular yarn. Heated air or steam are the preferred fluids because the apparatus can be considerably simpler and the flowing fluid will present no collecting and disposal pro lems. It is also possible to plastify the yarn simply by passing it through a swelling liquid. In such cases compressed air at ambient temperatures may be employed as the yarn impelling fluid.
For a more complete description of the process and apparatus of the present invention reference will now be made to the drawing wherein:
FIG. 1 is a sectional view of an embodiment of the apparatus of the present invention;
FIG. 2 is an enlarged sectional view of a portion ofthe nozzle end of the yarufeeding and heating device of FIG. 1;
FIG. 3 is an enlarged plan view of a portion of a barrier screen with a length of yarn thereon;
FIG. 4 is a sectional elevation taken on the line 44 of FIG. 3;
FIG. 5 is a view of a length of multifilament yarn which has ben textured in accordance with the present invention;
FIG. 6 is a sectional view of the yarn feeding tube and nozzle of another embodiment of the present invention;
FIG. 7 is a schematic representation of a portion of the apparatus of the present invention illustrating gas conveying, heating and collecting means;
FIG. 8 is a schematic view illustrating a different relationship between the nozzle and the barrier;
FIG. 9 is another schematic view illustrating the use of a continuous plane barrier;
FIG. 10 is a perspective view illustrating another plane barrier and the relationship of the nozzle thereto;
FIG. 11 is a schematic elevation of a complete yarn crimping apparatus in accordance with the present invention;
FIG. 12 is a sectional elevation of thefluid heating means, yarn feeding tube and nozzle of the apparatus of FIG. 11;
FIG. 13 is an enlarged detail of the lower end of the yarn feeding tube and nozzle of the apparatus of FIG. 12, and
FIG. 14 is a greatly enlarged detail of the nozzle of FIGS. 12 and 13.
Reference will now be made to FIG. 1 wherein there is illustrated one of the simplest embodiments of the pres ent invention. A thermoplastic yarn 11 is fed axially by a pair of feeder rollers 12 and 12a to a yarn feeding tube 21 which is jacketed with an electrical resistance coil 14. The feeding tube and heating coil 14 are surrounded by an outer jacket 13 which is spaced from the heater to provide an annular passageway 13a (FIG. 2). An opening 15 is provided for introduction of air under pressure which flows along substantially the complete length of the heating element and then comes in contact with the yarn 11 just outside a labyrinth seal 16 at the feed end of the outer jacket. The air then passes axially in a laminar stream through the feeding tube 21 and propels the yarn 11 toward the nozzle end 17. The nozzle 18 (FIG. 2) is of the De Laval injector type, and is positioned in close proximity to a wire mesh screen 19, which is mounted on a rotating drum 20.
In operation, the yarn is conveyed axially through the feeding tube and nozzle at substantially the same velocity with which it is delivered by the feeder rolls 12 and 12a and impinges upon the moving surface of screen 19 as shown in FIG. 2. During its passage through tube 21 the yarn is heated to a plastic condition. As the plastified yarn hits the screen it is deformed i.e. crimped due to the impact on the hard wires of the screen, whereas the air stream passes through the screen. Referring to FIGS. 3 and 4, it is seen that the yarn on the screen is quite voluminous due to its crimped filaments.
The sieve 19 is constantly rotated in order to present a fresh surface to the traveling yarn, but rotation is at a substantially lower linear velocity than that of the feed rollers 12 and 12a since the yarn is appreciably reduced in length by reason of its deformation on the screen. While it is difficult to prescribe a definitive ratio of the linear velocity of the feed rollers to the velocity of the screen it is reasonable to say that the screen is moved at a velocity between about and 75% of that of the input or feed rollers.
A pair of takeup rollers 22 and 22a are so positioned with respect to the screen 19 as to enable a temporary retention of the yarn on the impact surface. In the apparatus of FIG. 1 the deformed yarn remains on the screen from the point of impact to a point 23 on the drum 20.
In order to wind up the resulting crimped yarn with some degree of tension, the takeup rollers 22 and 22a are so operated as to remove the yarn from the screen at a linear speed slightly greater than the speed at which the screen is moving. By reason of the fact that the yarn is now crimped takeup speed must be substantially less than the rate at which the yarn impinges upon the screen. For example, the takeup device operates at a linear speed between about 50 and 90% of the speed of the feed rollers. In a typical example, the ratio of linear speeds of the feed rollers, moving screen and takeup rollers is about 100:55270.
Another yarn feeding member is illustrated in FIG. 6 wherein the feeding tube 21 is provided with a spaced jacket 24 which is adapted as at 25 for introduction of a hot fluid medium, for example air under pressure. The lower end of tube 21 and jacket 24 are shaped as at 26 and 27 respectively, to provide a modified injector nozzle which is positioned adjacent the barrier, for example, screen 19. In this embodiment the air or other flowing medium is exteriorly heated, and after passage of substantial quantities of hot gas the feeding tube 21 becomes hot and acts as a radiant heater for the yarn. However, the direct contact with the hot gas at the nozzle is generally sufficient to plastify the yarn.
Since considerable energy is expended in heating the gas and propelling the same through the yarn feeding member, it is desirable to conserve as much heat as possible in the gas, which of course requires collection and reuse of the gas after it has passed through the screen or been diverted in some other manner from the barrier. This may be accomplished as shown in FIG. 7 by providing an enclosure 28 about drum 20'. The enclosure is adapted as at 29 and 31 to provide exits for the crimped yarn and gas, respectively. Gas is withdrawn from enclosure 28 through conduit 32 by a compressor 33 after which it is delivered to a heating chamber 34 and then introduced to the yarn feeding member, the nozzle end 17 of which projects into enclosure 28.
While the barrier screen is preferably in the shape of a drum and the yarn is preferably directed at the outer surface of said drum as shown in FIGS. 1 and 7, the yarn may be impinged upon the inner side of a drum-shaped screen 19b, as shown in FIG. 8. In this embodiment the entire yarn feeding member is positioned inside of the screen drum 20a.
The yarn may also be impinged upon a plane irregular surface, for example, a continuous length or belt of screen material 19c (FIG. 9) moving about a pair of rollers 36, 37.
In still another embodiment of the present invention the yarn may be impinged upon a circular plane irregular impact surface such as screen 19d in FIG. 10, which'is suitably mounted on a rotating shaft 38. In this embodiment the time of residence of the yarn 11 On the screen may be controlled not only by the speed of rotation of the screen but also by adjusting the radial distance between the center of the screen and the point of impingement.
The apparatus of FIGS. 11-14 is a typical machine in accordance with the present invention for crimping a single yarn. Referring to FIG. 11, it is seen that the apparatus is vertically arranged with the yarn 11 being drawn from one of the pirns 41. Two such pirns are shown, and the one on the right is a spare pirn. The yarn 11 is drawn from the pirn by feed rollers 12, 12a, in which pair roll 12 is a driven pressure roll, through a yarn brake mechanism illustrated generally at 42, and thence by suitable guide rollers through a trough or other liquid container 43 where the yarn is moistened. The yarn then passes into the feeding tube, not shown, where it is contacted with heated air, for example, and discharged through nozzle end 17 in the usual manner. The feeding tube, heater and nozzle are enclosed by a cover member indicated generally at 44; The yarn impinges upon screen drum 20 which is rotated by means of a drive indicated at 46. It is then removed from the screen under slight tension exerted by a driven takeup roller 47. Intermediate the drum and the takeup roller, the crimped yarn passes in contact with a pivotal guide 51 which equalizes tension in the yarn and thence in contact with a further guide system 52. The yarn is finally wound under slight tension onto a spool or bobbin 53.
For details of those elements enclosed by member 44 reference will now be had to FIG. 12. The yarn feeding tube 21 is provided at its lower exit end with a yarn heating and nozzle member indicated generally at 54. Air under pressure from a source not shown, is conveyed through pipe 55, to opening 57 in member 54. The air is heated by a ceramic insulated electric heating element 56 whichsurrounds the pipe.
As seen in FIG. 13 member 54 consists of an upper hollow block 58 which is rigidly secured to the machine frame 59. Block 58 is so constructed as to provide an annular manifold 61 intermediate its inner and outer concentric walls, and its outer wall is bored as at 57 to provide access from pressurize air line 55 to the manifold. The inner wall of block 58 is threaded as at 62 to receive a nozzle block 63 which is axially bored and counterbored as shown and the counterbore is threaded as at 73. The
lower end 70a of the counterbore is tapered as at 66 (FIG. 14) into bore 70. The nozzle block 63 is also bored as at 67 to permit access from the manifold 61 to the lower end 70a of the counter-bore.
Referring to FIG. 14, a tube 68 is positioned in the bore 70 by a forced or friction fit, and the upper end of the tube 68 is bored or otherwise machined to produce a taper 71, which tapered portion serves as an element of the injection nozzle. The wall of the lower end of feeding tube 21 is tapered as shown at 74 and serves as another element of the injector. The tapered portions of tubes 21 and 68 which come in contact with the air stream are highly polished.
An elongated hollow bolt 72 is secured by a friction fit about tube 21 and is threaded into nozzle block 63. It will be seen that the lower end of bolt 72 is spaced from the tapered end of tube 21, and also that the lower end of counterbore 70a is not threaded. When the bolt 72 is in position in the block its lower end serves as the upper wall of an axial chamber 64 which communicates with bore 67.
A spacing sleeve 75, having a flanged head 78, is positioned about hollow bolt 72 and is free to move axially relative thereto. The lower end of sleeve 75 is provided with lock points indicated generally at 76 whichengage suitable recesses in the upper surface of the nozzle block 63. A lock nut 77 is positioned on the bolt 72 just above the head 78 of the spacer sleeve. When the lock nut is tightened all parts are rigidly held in the position shown.
' The nozzle is adjusted as indicated by the dotted lines 79 in FIG. 13 by backing off the lock nut and screwing down or backing off the hollow bolt, thus inserting or withdrawing the tapered end of tube 21, after which the lock nut is reset.
In operation of the apparatus of FIGS. 12-14 heated air enters the manifold 61 and passes into chamber 64 where it heats tube 21 and the other elements of the heating and nozzle member 54, and passes thence through the nozzle and into tube 68. By reason of the zone of low pressure in and adjacent the tapered end of tube 21 the yarn'travels along with the air through tube 68 and onto the screen or other barrier. The yarn is easily plastified in passing through member 54 and by its direct contact with the heated air. The air passes through chamber 64 and tube 68 in a laminar stream and any substantial formation of turbulant air streams is prevented.
The process of the present invention is further illustrated by the following non-limiting examples.
Example 1 A 210 denier, 34 filament nylon yarn having a twist of 80 turns per meter was uniformly moistened with water and fed to the apparatus of FIG. 1 at a speed of 93.5 meters per minute, and propelled through the nozzle by a stream of air at 3 atmospheres absolute pressure and 270 C. The yarn in plastic condition as a result of its passage through the heating element and contact with the heated air was directed against a drum-shaped rotating70 mesh wire screen and removed from the screen at a speed of 69 meters per minute after which it was conveyed to a winding apparatus. The resulting crimped yarn was voluminous and had a crimp contraction of 19%.
Example 2 The nylon yarn of Example 1 was uniformly impregnated with a 1% aqueous solution of phenol and then impinged at a speed of 100 meters per minute with the aid of air at 3.5 atmospheres'absolute pressure and 200 C. against a rotating 100 mesh wire screen. The yarn was removed from the screen at a speed of 70 meters per minute and wound on a bobbin. The crimped voluminous yarn obtained had a crimp contraction of 9.5%
Example 3 A 140 denier, 68 filament nylon yarn having a twist of 20 turns per meter was propelled by air at 3 atmospheres absolute pressure and 265 C. at a speed of meters per minute against a. continuously rotating mesh wire screen as shown in FIG. 9. The yarn was removed from the screen at a speed of 70 meters per minute and Wound on a bobbin. Two such yarns were plied together with 100 turns per meter in the S direction and the finished crimped voluminous yarn has a crimp contraction of 9.5%.
Example 4 A slightly twisted 90 denier, 30 filament yarn of a po-' A 100 denier, 48 filament polyethyle'neglycol .terephthalate yarn having 30 turns per meter was uniformly impregnated with a 2% aqueous solution of phenol and processed as set forth in Example 2. The crimped voluminous yarn so produced had a crimp contraction of 4.7%. 5
Example 6 A 100 denier, 36 filament polyacrylonitrile yarn was passed through an injector nozzle at a yam speed of 64 meters per minute. Compressed air at 280 C. plastified and propelled the yarn against a round rotating mesh wire screen as illustrated in FIG. 10. The yarn was removed from the rotating screen at a speed of 58 meters per minute, cooled in air and subsequently wound onto a bobbin. The crimped voluminous yarn so produced had a satisfactory crimp contraction.
Example 7 A slightly twisted 200 denier, 33 filament cellulose acetate yarn made by spinning secondary acetate, was impregnated with a liquid mixture consisting of one part by volume of acetone alcohol and 99 parts by volume of water. It was then fed through an injector nozzle in accordance with the present invention at a speed of 65 meters per minute. In the nozzle it was plastified with compressed air at 265 C., and impinged directly upon a rotating porous clay cylinder which easily let the air pass through it. The resulting deformed yarn was removed from the olay'cylinder at a speed of about 59 meters per minute. The crimped, voluminous yarn was cooled in air and wound up. It had a satisfactory crimp contraction.
Example 8 A slightly twisted thread of 88 denier degummed natural silk was uniformly moistened with water and then passed through an injector nozzle at a speed of 64 meters per minute. to the nozzle and propelled the yarn against a rotating mesh wire screen drum. The yarn was subsequently removed from the drum at a speed of 52 meters per minute, cooled and wound on a bobbin. The crimped yarn so produced was voluminous and had a crimp contraction which was entirely satisfactory.
Crimp contraction is defined as the contraction of the yarn which results when the crimp is completely developed by wetting. This characteristic is determined and measured as follows:
An eight yard length of textured yarn is removed from each of five bobbins or cones and each length is wound onto a circular reeling device having a circumference of one yard, under sufiicient tension to cause the yarn to lie flat, e.g. about 0.1 g./den ier. The yarn is then re moved from the reeling device in a skein which is eighteen Compressed air at 360 C. was introduced inches long and consists of sixteen lengths of yarn. Each of the five skeins so formed is treated for minutes in distilled water at 6070 C. in a tensionless condition. It is then removed from the water and dried without tensron.
Each skein is then completely wet out by immersion for 30 seconds in water at 60 C. containing either 2 g./liter Santomerse No. 1 Flake (Monsanto Chemical Co.) or the same quantity of Perminal (Imperial Chemical Industries, Ltd.). The skein is then hung on a hook in the wet state and loaded with 0.2 g./denier (e.g. 100/2 denier yarn with 640 g.). Care is taken to be sure that the skein hangs flat.
After loading for one minute the length (a) of the wet stretched skein is determined. Then the weight is removed and the skein is dried at 5060 C. while hanging free without load. After cooling for one hour the skein is loaded with 0.002 g./denier and after one minute the length (b) is again determined. From these measurements, crimp contraction is deter-mined as follows:
Percent crimp contraction: 100- 1002b/ Ea) where and deform the yarn, the stream being diverted from the yarn at the barrier screen and the yarn being set on the screen while free from fluid disturbance, feed means for continuously forwarding the yarn into said nozzle, and takeup means for removing the yarn from the barrier screen at a speed between about and of the forwarding speed of the feed means.
2. Apparatus as defined in claim 1 wherein said barrier screen is the surface of a rotating screen drum.
3. Apparatus as defined in claim 1 wherein said barrier screen is the surface of a traveling screen belt.
4. Apparatus as defined in claim 1 wherein said barrier screen is the surface of a circular plane screen rotating in the plane of the screen.
5. Apparatus as defined in claim 1 wherein said lbarrier screen is disposed within a closed chamber provided with means for recycling heated fluid to said nozzle.
References Cited by the Examiner UNITED STATES PATENTS 2,202,030 5/ 1940 Siegfried.
2,204,341 6/ 1940 Cobb.
2,294,957 9/ 1942 Caldwell.
2,313,630 3/1943 Dockerty.
2,379,824 7/ 1945 Mummery.
2,395,371 2/1946 Dockerty.
2,435,891 2/1948 Lodge 2,563,986 8/1951 Bauer.
2,584,043 1/ 1952 Oberly.
2,874,446 2/ 1959 Sellers 281 X 2,931,076 4/1960 Clark 19-156.3 X
3,016,599 1/1962 Perry.
3,036,357 5/1962 Cook et al. 28-1 3,142,147 7/1964 Betsch 57 157 X 3,148,101 9/1964 Allrnan et a1. 2872 X DONALD W. PARKER, Primary Examiner.
R. R. MACKEY, Assistant Examiner.

Claims (1)

1. IN APPARATUS FOR CRIMPING THERMOPLASTIC TEXTILE YARN A NOZZLE FOR PASSAGE OF THE YARN IN AN AXIAL DIRECTION, A MOVABLE BARRIER SCREEN FOR RECEIVING THE YARN FROM THE NOZZLE, THE NOZZLE HAVING ONE END CLOSELY ADJACENT TO A PORTION OF THE SCREEN AND BEING SUBSTANTIALLY PERPENDICULAR SO THAT PORTION OF THE SCREEN, MEANS FOR CONTINUOUSLY MOVING SAID BARRIER SCREEN, MEANS FOR PASSING A LAMINAR STREAM OF HEATED FLUID THROUGH THE NOZZLE FOR PLASTIFYING AND PROPELLING THE YARN AGAINST THE BARRIER SCREEN IN A PLASTIC CONDITION WITH SUFFICIENT FORCE TO MECHANICALLY DEFORM THE YARN, THE STREAM BEING DIVERTED FROM THE YARN AT THE BARRIER SCREEN AND THE YARN BEING SET ON THE SCRREEN WHILE FREE FROM FLUID DISTURBANCE, FEED MEANS FOR CONTINUOUSLY FORWARDING THE YARN INTO SAID NOZZLE, AND TAKEUP MEANS FOR REMOVING THE YARN FROM THE BARRIER SCREEN AT A SPEED BETWEEN ABOUT 50 AND 90% OF THE FORWARDING SPEED OF THE FEED MEANS.
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US3457611A (en) * 1967-10-10 1969-07-29 Hercules Inc Apparatus for crimping thermoplastic yarns
US3656214A (en) * 1969-08-26 1972-04-18 Mitsubishi Rayon Co Crimping apparatus for manufacturing a bulky yarn
US3665567A (en) * 1970-04-23 1972-05-30 Uniroyal Inc Yarn rebound texturing apparatus and method
US3720983A (en) * 1968-08-06 1973-03-20 H Hino Apparatus for the manufacture of crimped bulky filaments
US4160307A (en) * 1976-11-16 1979-07-10 Chevron Research Company Improvements in thermoplastic yarn rebound texturizing methods
US4296535A (en) * 1975-10-02 1981-10-27 Allied Chemical Coporation Apparatus for texturizing continuous filaments
US5135811A (en) * 1986-02-04 1992-08-04 Dow Corning Corporation Polyamide yarn provided with a built-in antibacterial and method for its production
EP0784109A2 (en) 1996-01-12 1997-07-16 Maschinenfabrik Rieter Ag Method and apparatus for the manufacture of a multi-coloured yarn composed of differentially dyed continuous filament yarns
US6076345A (en) * 1997-02-26 2000-06-20 Maschinenfabrik Rieter Ag Method and apparatus for generating a yarn composed of at least two yarn components

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US3457611A (en) * 1967-10-10 1969-07-29 Hercules Inc Apparatus for crimping thermoplastic yarns
US3720983A (en) * 1968-08-06 1973-03-20 H Hino Apparatus for the manufacture of crimped bulky filaments
US3656214A (en) * 1969-08-26 1972-04-18 Mitsubishi Rayon Co Crimping apparatus for manufacturing a bulky yarn
US3665567A (en) * 1970-04-23 1972-05-30 Uniroyal Inc Yarn rebound texturing apparatus and method
US4296535A (en) * 1975-10-02 1981-10-27 Allied Chemical Coporation Apparatus for texturizing continuous filaments
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US5135811A (en) * 1986-02-04 1992-08-04 Dow Corning Corporation Polyamide yarn provided with a built-in antibacterial and method for its production
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US6119320A (en) * 1996-01-12 2000-09-19 Maschinenfabrik Rieter Ag Method and apparatus for producing a multicolored yarn from differently colored part-threads of endless filament
US6076345A (en) * 1997-02-26 2000-06-20 Maschinenfabrik Rieter Ag Method and apparatus for generating a yarn composed of at least two yarn components
US6442923B1 (en) 1997-02-26 2002-09-03 Maschinenfabrik Rieter Ag Method and apparatus for generating a yarn composed of at least two yarn components

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