US2956328A - Bulk beamer process and apparatus for manufacturing bulk yarn - Google Patents

Bulk beamer process and apparatus for manufacturing bulk yarn Download PDF

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US2956328A
US2956328A US602868A US60286856A US2956328A US 2956328 A US2956328 A US 2956328A US 602868 A US602868 A US 602868A US 60286856 A US60286856 A US 60286856A US 2956328 A US2956328 A US 2956328A
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yarn
bulked
bulk
rolls
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Wendell G Faw
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Eastman Kodak 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

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  • This invention relates to an apparatus and process for converting continuous multi-filament yarn directly in one operation into a bulked yarn wound on a beam suitable for use in subsequent textile operations. More particularly this invention relates to special process and apparatus for bulking a plurality of ends of heavy denier yarn, winding upthe bulked yarn on a beam in order to obtain a bulked yarn especially suitable for direct use as the yarn supply on a carpet machine of the needle tufting type.
  • This invention has for one object to provide an improved process and apparatus for converting continuous multi-filament yarn directly into bulked yarn on a beam. Still another object is to provide improved process and an apparatus from which may be obtained a better supply package of bulked yarn for rug machines. Another object is to simplify the process and apparatus used for producing bulk yarn for the rug trade. Still another object is to prepare bulked yarn in a form that expensive recreeling and handling operations are minimized or eliminated and non-uniform tufting is eliminated due to tension irregularities in withdrawing yarn from individual cores. Another object is to provide a novel apparatus combination for carrying out the aforesaid processes. Still another object is to provide an apparatus wherein yarn may be bulked and beamed and wherein particularly uniformity and evenness of the yarn on the beam is obtained by a common drive arrangement of the apparatus parts. Other objects will appear hereinafter.
  • Fig. 1 is a semi-diagrammatic, side elevation, schematic view of the overall combination of apparatus arrangement in which the yarn may not only be bulked, but may be beamed;
  • Fig. 2 is a detailed, schematic view of alternative construction of a part of the apparatus
  • Fig. 3 is a detailed, sectional view of an air jet construction such as may be used in my apparatus.
  • a plurality of yarn ends 1, 1', 1", etc., of a suitable type of yarn are contained on a plurality of conventional supply packages 2, 2', 2", etc.
  • These yarn ends are collected into a sheet of ends in conventional manner by suitable guides and eyelets (not shown) and passed around the weighted idler roll 3 and then around feed roller 4.
  • This feed roller 4 is adapted to run at a predetermined speed, which speed may be substantially exactly correlated with the speed of operation of certain other parts of my apparatus as will be explained in further detail hereinafter.
  • feed roller 4 might be operated at a speed of say around 50 yds./min. surface speed.
  • the sheet of yarn ends from feed roller 4 are fed to a bank of bulking jets 5, 5, 5", etc.
  • These jets are preferably of a construction such as shown in Fig. 3 and which will be described in detail hereinafter. That is, each individual yarn end is passed through a separate jet. For example, end 1 passes through jet 5, end 1 through jet 5', and end 1" through jet 5".
  • these jets may be supplied by the same air supply 15 thereby rendering it possible to bulk the yarn substantially exactly the same, if this is desired. In other words, it is possible in my new apparatus to give the yarn substantially the same identical treatment, thereby obtaining remarkable uniformity of product.
  • the yarn ends thus bulked pass from the jets preferably at an abrupt angle asshown, to the take-up roll 7 with its associated idler roll 6.
  • These take-up rolls are designed to revolve at a slower speed than rolls 3 and 4.
  • the surface speed of the take-up rolls might be 20% slower than the surface speed of rolls 3 and 4. As will be described hereinafter, this can be accomplished in a correlated manner by means of the common drive.
  • This beam may be the usual beam employed in the textile trade for beaming yarn.
  • the yarn passes through a reed assembly 20 or other appropriate means for aligning and distributing the bulk yarn on the beam 8.
  • the wind-up on beam 8 is accomplished by means of the rotating drum 9 whose surface speed slightly exceeds that of rolls 6 and 7 and as observed from the drawing, this speed may be correlated by means of a special drive.
  • a special drive in accordance with the present invention for the rolls 3 and 4, 6 and 7, drum 9 and beam 8 comprises a drive motor 10 which is interconnected by a belt or chain drive with a set of sprockets. That is, a sprocket or pulley 11 of a certain size may be provided for driving roll 7 at 23. By varying the respective diameters of these drive means 11 and 23 it can be seen that take-up roll 7 can be driven at any predetermined speed. By this construction it is very easy to control the bulking of the yarn. When the roll 7 is driven slower this permits more contraction of the yarn; hence greater bulk. In a similar manner the central sprocket drive means 11' is connected with 12 and 13.
  • Fig. 2 as an alternative to the takeup roll assembly 6 and 7, construction such as shown in this figure may be used. That is, the bulked yarn sheet from the 'jet maybe passed oyer a rod 21 and then back around another rod'22. These parts are constructed so that the rodsmay be rotated togive the desired degree of snubbing or wrap of the yarn around the rods. This can be variedto vary the tension of the yarn wound on the beam.
  • suitable means for rotating the rods might comprise a central horizontal axle 25, 26 on the rod assembly supported in plain bearings or holes in the machine framework withlocking set screws to hold the rod assembly inthe desiredposition.
  • the rod assembly is rotatedclockwise; if less tension is desired, it is rotated counterclockwise. If still higher wind-up tensionsare required, additional rods may be added to increase the amount-of snubbing of the yarn.
  • a jet construction Such as I prefer to use for parts, 5, and 5" in Fig. 1.
  • This jet device comprises the body member 31 which has threaded into its upper enda tube 3.2 terminating in the nozzle 33 at its lower end. Closely adjacent and concentric to the nozzle is an orifice plate 34. Just below and abutting the orifice plate is, a ven-turi tube 35 threaded into the body 3 1;andhaving anentrance throat36 and a straight portion 37 aboutegual in diameter to theorifice plate opening.
  • An exit throat 38 having ataper of about included angleisprovided in the jet device at the exit end thereof.
  • An entrance for, air is provided at 39, which entrance leads into the air chamber 40.
  • Yarn 1 enters the ntake tube 32. and is mixed with the air stream at the orifice plate 34. Mixing continues until the yarn leaves the exit taper into the venturi. Here the expansion of the air also expands the bundle of filaments until the filaments are separated and spaced apart. As discussed above, the yarn leaves the jet at an abrupt angle (as it is taken up on take-up rolls 6 and 7) and the turbulence of air and loosened filament structure at this point results in a tanglingv of the filaments.
  • the air pressure used in operating such jet is avariable depending on the degree of entanglement or loopiness desired, and on the filament size. Larger filaments and heavier denier yarns and faster processing speeds usually require higher air pressures.
  • Preferably clean, dry, oilfreeair is employed and as shown in Fig. l the air is cleaned by. filter 18.
  • a pressure regulator isinserted at 17 and a gauge at 13 serves to give adequate control of the air pressure.
  • the yarn which will be contained on packages 2, 2', 2" may be anyof the usual types of yarn for manufacturing rugs.
  • the yarn might comprise a material with 240 filaments of 20 denier size, or 480 filaments of .10 denier size.
  • the yarn on the packages might be composed of various filament sizes to approximate the filament size disposition found in wool.
  • the overall choice of the supply would be such that there would be an average filament denier of about 9 denier per filament, and a range from 2 to 25
  • Such type of yarn with various filament sizes as indicated automatically delivers a beamed yarn made up into a rugwhich comparesfavorably with wooL-
  • various other yarns of different compositions and cross sections may be processed in accordance with the present invention.
  • the yarns may be of Y or 0 cross section or other such special cross section, and the yarn.
  • lulose acetate may be polyester, polyamide, polyacrylonitrile or the like synthetics.
  • the yarn in all instances, as is believed apparent from the description which has preceded, would be multi-filament having at least 30 filaments at a minimum.
  • the yarn may be either twisted-or untwisted. In some instances a twist of 1 to 7 turns would be employed, although in general on carpet yarns zero twist is preferred.
  • suitable yarn from packages 2 is drawn up from the packages by feed rolls which are driven at a certain predetermined;spe ed by, pulley 12..
  • the plurality ofyarn ends are simultaneously fed through a plurality of jets ,5, 5', 5", etc., .tl 1ese jets being of construction ale ready discussed in detail under Fig. 3, and have. supplied thereto a uniform and'cornmonsourceof air throughthe air header.
  • the plurality of yarnends are uniformly bulked and then taken up-by take-up rolls 6 and 7, said rolls being driven at a predetermined roller speed by means of drive 23.
  • the bulked yarn from take-up rolls 6 and 7 then is packaged on the beam 8. In this manner not onlyis the yarn on a beam and thereby. ina much easier form for utilization inrug making, but since the yarn has been substantially uniformly bulked and held under comparable tension conditions throughout my process, the resultant yarn is more uniform than might be, experienced from making rugsfrom individual packages.
  • Example I In accordancewith this example eight zero twist yarn supply packages containing 4800 denier, 400 filament, 0 section cellulose ester yarn are used.
  • the yarn ends from the supply packages pass around the weighted idler roll 3 and then around feed roller 4 which is operating at a speed of 25 yd/min. From the feed roller the yarn ends are fed to the jets (5, 5, 5") where filtered air at a pressure of 20 p.s.i. gage bulks the yarn. After bulking in accordance with my invention, the yarn ends pass from the jetsto take-up roll 7 operating at a speed of 20 yd./min. In passing from the jet to the take-up rolls the filaments are severely tangled due to the turbulence of the air.
  • the bulked, tangled yarn then proceeds to the wind-up on beam 8, which is accomplished by means of drum 9 driven at a surface speed of 20.5 yd./min.
  • the speed of take-up roll 7an'ddrum 9 are directly correlated to the predetermined rate of speed of feed roll 4.
  • the yarn thus produced in accordance with my invention comprised 5300 denier, 400 filament 0 section bulked rug yarn containing crunodal type yarn loops and a severely entangled filament structure which resists theremoval of the loops under normal processing of the yarn into a rug.
  • beam 8 was full it was used as the yarn supply to an eight needle tufting machine and swatches of rug material'were made. Examination and testing of these swatches indicated an excellent quality, uniform product had been obtained. 7
  • Example II Eight supply packages of regular section cellulose acetate, 2200 denier, filament, .75 Z twist yarn are used for the yarn supply.
  • the feed roll '4 speed was 50 y.p.m.
  • the yarn was treated in the jets at 25 p.s.i. air pressure and'then passed to the take-up rolls 6 and 7 which were set at a speed of 40 y.p.m. It then passed to the beam which was operated at 41 y.p.m.
  • the treated yarn was characterized by a tangled loopy filament appearance and the-final denier was 2700.
  • ExampleIII 7 The yarn of Example H was treated in the same manner except that the rolls 6 and 7 were replaced by the friction rods of Fig. 2.
  • the yarn was fed to the jets by the feed rolls at a speed of 50 y.p.m., From the jets it passed over and around the tension rods so that 270 of yarn wrap on the rods was obtained.
  • the beam speed was 41 y.p.m.
  • The'yarn' tension between the jets and the tension rods was 0-10' grams ineach yarn strand.
  • the tension in each yarn strand'be'tween the rods and the beam was 200 to 250 grams.
  • any size beam may be produced.
  • a rug machine requiring 800 ends of yarn beams containing 80 ends of yarn each could be made up. That is, in Fig. 1 the number of threads, jets and the like would be increased so that beam 8 of Fig. 1 would have 80 ends wound thereon.
  • the denier of the yarn may be varied for any particular end use. While I have described in particular the preparation of beams of bulked yarn for use in carpet manufacture, and the process and apparatus of the present invention are particularly useful for this purpose, my invention is not limited to producing beamed yarn for only this purpose. For example, 1000 denier beamed yarn produced in accordance with the present invention may be used for chenille bed spreads. Or, in a similar manner, 300 denier yarn may be processed to obtain warp beams for use in woven fabric looms.
  • the particular air pressure used and other details of operation may be varied. While in the above examples air pressures of lbs/sq. in. gage have been mentioned, the air pressure may vary from say 8 lbs./ sq. in. to 50 lbs/sq. in.
  • the jet of Fig. 3 is designed so that in the area of the orifice and venturi throat the air velocity is sonic or supersonic.
  • the yarn prior to processing in my apparatus is preferably treated with a yarn treating agent having a high electrical resistivity such that the generation of static electricity on the yarn is not appreciably inhibited, which static charge aids in causing filament separation in the bulking jet.
  • Said agent also has the property of causing the yarnto have a high scroop value or ratio of static friction to dynamic friction, said scroop being of material assistance in preventing the removal of the yarn loops and entanglement in subsequent processing under tension of the yarn.
  • a valuable feature of my process and apparatus is that I am able to bulk or loft zero twist yarn and package it without imparting twist thereto.
  • Such processing of zero twist yarn is specifically illustrated in Example I hereof.
  • the speed is generally kept below 50 yds/min. and the air pressure below 50 lbs./ sq. in.
  • the yarn on packages 2, 2', etc. may have, for example, from /5 to 7 or 8 turns therein.
  • the process for the manufacture of beamed, bulked yarn particularly suitable for carpet manufacture which comprises providing a plurality of packages of yarn from which the yarn is delivered to feed rolls, said yarn being characterized by being continuous, multi-filament yarn of'varying denier from 3 to 20 denier and having fiber distribution as follows: l0%--3 D/F, 20%5 D/F, 40%-8 D/F, 15%l2 D/F, 10%l6 D/F, 5%--20 D/F, passing said yarn of varying denier through a plurality of air jets, said plurality of jets being supplied by a common air supply whereby the ends are subjected to substantiallythe same air treatment and are thereby bulked, taking the bulked sheet of ends away from said jets by means of take-up rolls operating at a lower speed than the speed of the first-mentioned rolls, passing the bulked .yarn thus taken up on-the last mentioned rolls to a rotating beam, said passage being through means where- 'by the bulk yarn is uniformly positioned on said
  • the process for manufactming beamed, bulked yarn which comprises gathering from a plurality of separate packages a sheet of continuous, multi-filament yarn ends, conducting these ends around a single elongated feed roller for all of said ends rotating at a predetermined speed, passing said sheet of ends from the single elongated feed roller through a plurality of air jets, said plurality of jets being supplied by a common air supply whereby the ends are subjected to substantially the same air treatment and are thereby bulked, taking the bulked sheet of ends away from said jets by means of a single elongated take-up roll operating at a lower speed than the speed of the.
  • first-mentioned roll passing said bulked yarn to a rotating beam of a length sufiicient to receive all of said ends, said passage being through means whereby the bulk yarn is uniformly positioned on said beam, and rotating the beam containing the bulk yarn by drive means which is correlated to the rotation of the other rolls aforementioned.
  • the process of manufacturing beamed bulked yarn suitable for rug production which comprises feeding at least 8 ends of zero twist yarn of 0 section filaments from separate packages onto -a single feed roll which receives all of said ends, feeding the yarn aforesaid at the same rate of speed for all the yarn through a plurality of air bulking jets operating from a common air supply, taking up the bulked yarn from said jets onto a single elongated take-up roll at the same rate of speed for all the yarn, delivering the bulked yarn from the take-up roll to a beam, and rotating the beam and rolls by means of a common and correlated drive whereby the take-up roll is operated at a slower speed than the feed roll and the bulked yarn is wound on the beam in a uniform manner.
  • An apparatus for producing beamed, bulked yarn which comprises means for feeding yarn ends from a plurality of packages to a single elongated feed roll for all of said ends, a plurality of air jets provided with a common air supply positioned between said feed roll and a single elongated take-up roll for all of said ends, said take-up roll being adapted to deliver bulk yarn through distribution means to a beam whereby the bulked yarn is deposited uniformly on said beam, and driving means interconnected and associated with all of said rolls and said beam so that the take-up rolls may be rotated at a slower speed than both the feed rolls and the beam.

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Fluid Mechanics (AREA)
  • Mechanical Engineering (AREA)
  • Textile Engineering (AREA)
  • Yarns And Mechanical Finishing Of Yarns Or Ropes (AREA)

Description

0a. 18, 1960 w. G. FAW A 2,956,328
BULK BEANER PROCESS AND APPARATUS FOR MANUFACTURING BULK YARN Filod Aug. 8, 1956 TENS/0N WE/VDELL 6. FAW
M VNJLL ATTORNEYS United States Patent BULK BEANIER PROCESS AND APPARATUS FOR MANUFACTURING BULK YARN Filed Aug. 8, 1956, Ser. No. 602,868
6 Claims. (Cl. 28-32) This invention relates to an apparatus and process for converting continuous multi-filament yarn directly in one operation into a bulked yarn wound on a beam suitable for use in subsequent textile operations. More particularly this invention relates to special process and apparatus for bulking a plurality of ends of heavy denier yarn, winding upthe bulked yarn on a beam in order to obtain a bulked yarn especially suitable for direct use as the yarn supply on a carpet machine of the needle tufting type.
In the prior art it has been the practice to supply rug machines with individual supply packages each containing only one end of yarn. This may result in considerable loss of time in recreeling a rug tufting machine when the thousand or more individual packages run empty. Prior to the present invention it has been the practice to prepare bulk yarn for the carpet trade by bulking each end of yarn on an individual spindle position of a redraw or twisting machine with a subsequent reconing process. It will be recognized that such prior practices do no exhibit maximum efliciency and may be wasteful of manpower and expensive machinery. In addition to the economic waste just mentioned, the handling of yarn for the rug trade on separate packages may present further problems in that there may be some lack of uniformity in the yarn. That is, some of the yarn on certain individual packages having been prepared under different tension conditions may not, when fabricated, exhibit the same loop structure or appearance as other yarn bulked under diiferent conditions.
It is apparent, therefore that the development of a process and apparatus whereby bulked yarn in the form of a plurality of ends of continuous multi-filament bulk yarn on a section beam in suitable form for direct use as the supply package on a rug machine, represents a highly desirable result.
This invention has for one object to provide an improved process and apparatus for converting continuous multi-filament yarn directly into bulked yarn on a beam. Still another object is to provide improved process and an apparatus from which may be obtained a better supply package of bulked yarn for rug machines. Another object is to simplify the process and apparatus used for producing bulk yarn for the rug trade. Still another object is to prepare bulked yarn in a form that expensive recreeling and handling operations are minimized or eliminated and non-uniform tufting is eliminated due to tension irregularities in withdrawing yarn from individual cores. Another object is to provide a novel apparatus combination for carrying out the aforesaid processes. Still another object is to provide an apparatus wherein yarn may be bulked and beamed and wherein particularly uniformity and evenness of the yarn on the beam is obtained by a common drive arrangement of the apparatus parts. Other objects will appear hereinafter.
For a further understanding of our invention reference will be made to the attached drawing forming a part of the present application. In the attached drawing:
Fig. 1 is a semi-diagrammatic, side elevation, schematic view of the overall combination of apparatus arrangement in which the yarn may not only be bulked, but may be beamed;
Fig. 2 is a detailed, schematic view of alternative construction of a part of the apparatus;
Fig. 3 is a detailed, sectional view of an air jet construction such as may be used in my apparatus.
Referring now to Fig. 1, a plurality of yarn ends 1, 1', 1", etc., of a suitable type of yarn, are contained on a plurality of conventional supply packages 2, 2', 2", etc. These yarn ends are collected into a sheet of ends in conventional manner by suitable guides and eyelets (not shown) and passed around the weighted idler roll 3 and then around feed roller 4. This feed roller 4 is adapted to run at a predetermined speed, which speed may be substantially exactly correlated with the speed of operation of certain other parts of my apparatus as will be explained in further detail hereinafter. For example, feed roller 4 might be operated at a speed of say around 50 yds./min. surface speed.
The sheet of yarn ends from feed roller 4 are fed to a bank of bulking jets 5, 5, 5", etc. These jets are preferably of a construction such as shown in Fig. 3 and which will be described in detail hereinafter. That is, each individual yarn end is passed through a separate jet. For example, end 1 passes through jet 5, end 1 through jet 5', and end 1" through jet 5". However, it will be noted that these jets may be supplied by the same air supply 15 thereby rendering it possible to bulk the yarn substantially exactly the same, if this is desired. In other words, it is possible in my new apparatus to give the yarn substantially the same identical treatment, thereby obtaining remarkable uniformity of product.
The yarn ends thus bulked pass from the jets preferably at an abrupt angle asshown, to the take-up roll 7 with its associated idler roll 6. These take-up rolls are designed to revolve at a slower speed than rolls 3 and 4. For example, the surface speed of the take-up rolls might be 20% slower than the surface speed of rolls 3 and 4. As will be described hereinafter, this can be accomplished in a correlated manner by means of the common drive.
'Ihe take-up rolls are positioned in series with the beam 8. This beam may be the usual beam employed in the textile trade for beaming yarn. On the way to the beam the yarn passes through a reed assembly 20 or other appropriate means for aligning and distributing the bulk yarn on the beam 8. The wind-up on beam 8 is accomplished by means of the rotating drum 9 whose surface speed slightly exceeds that of rolls 6 and 7 and as observed from the drawing, this speed may be correlated by means of a special drive.
That is, a special drive in accordance with the present invention for the rolls 3 and 4, 6 and 7, drum 9 and beam 8 comprises a drive motor 10 which is interconnected by a belt or chain drive with a set of sprockets. That is, a sprocket or pulley 11 of a certain size may be provided for driving roll 7 at 23. By varying the respective diameters of these drive means 11 and 23 it can be seen that take-up roll 7 can be driven at any predetermined speed. By this construction it is very easy to control the bulking of the yarn. When the roll 7 is driven slower this permits more contraction of the yarn; hence greater bulk. In a similar manner the central sprocket drive means 11' is connected with 12 and 13. Here again by the choice of suitable size sprockets or sheaves, or by using other devices for obtaining different speeds as may be chosen, the entire control of the feed and take-up of the yarn through my apparatus may be controlled, if desired. Inasmuch as all of these parts may be driven by the common motor drive 10, uniformity of product is achieved.
Referring now to Fig. 2, as an alternative to the takeup roll assembly 6 and 7, construction such as shown in this figure may be used. That is, the bulked yarn sheet from the 'jet maybe passed oyer a rod 21 and then back around another rod'22. These parts are constructed so that the rodsmay be rotated togive the desired degree of snubbing or wrap of the yarn around the rods. This can be variedto vary the tension of the yarn wound on the beam. In further detail, suitable means for rotating the rods might comprise a central horizontal axle 25, 26 on the rod assembly supported in plain bearings or holes in the machine framework withlocking set screws to hold the rod assembly inthe desiredposition. If more tension is;des iredin the yarn going onto the beam, the rod assembly is rotatedclockwise; if less tension is desired, it is rotated counterclockwise. If still higher wind-up tensionsare required, additional rods may be added to increase the amount-of snubbing of the yarn.
Referring now to Fig. 3, I have shown in this figure, on an enlarged scale, a jet construction Such as I prefer to use for parts, 5, and 5" in Fig. 1. This jet device comprises the body member 31 which has threaded into its upper enda tube 3.2 terminating in the nozzle 33 at its lower end. Closely adjacent and concentric to the nozzle is an orifice plate 34. Just below and abutting the orifice plate is, a ven-turi tube 35 threaded into the body 3 1;andhaving anentrance throat36 and a straight portion 37 aboutegual in diameter to theorifice plate opening. An exit throat 38 having ataper of about included angleisprovided in the jet device at the exit end thereof. An entrance for, air is provided at 39, which entrance leads into the air chamber 40. Yarn 1 enters the ntake tube 32. and is mixed with the air stream at the orifice plate 34. Mixing continues until the yarn leaves the exit taper into the venturi. Here the expansion of the air also expands the bundle of filaments until the filaments are separated and spaced apart. As discussed above, the yarn leaves the jet at an abrupt angle (as it is taken up on take-up rolls 6 and 7) and the turbulence of air and loosened filament structure at this point results in a tanglingv of the filaments.
The air pressure used in operating such jet is avariable depending on the degree of entanglement or loopiness desired, and on the filament size. Larger filaments and heavier denier yarns and faster processing speeds usually require higher air pressures. Preferably clean, dry, oilfreeair is employed and as shown in Fig. l the air is cleaned by. filter 18. A pressure regulator isinserted at 17 and a gauge at 13 serves to give adequate control of the air pressure.
The operation of my new apparatus is believed apparent to a substantial extent from the description which has al ready been set forth. However a brief recapitulation will aid in a better understanding of the present invention. Referring to Fig. l, the yarn which will be contained on packages 2, 2', 2" may be anyof the usual types of yarn for manufacturing rugs. For example, the yarn might comprise a material with 240 filaments of 20 denier size, or 480 filaments of .10 denier size.
A particularly interesting aspect of yarn choice is as follows. The yarn on the packages might be composed of various filament sizes to approximate the filament size disposition found in wool. For example, considering a carpet yarn, the overall choice of the supply would be such that there would be an average filament denier of about 9 denier per filament, and a range from 2 to 25 Such type of yarn with various filament sizes as indicated automatically delivers a beamed yarn made up into a rugwhich comparesfavorably with wooL- In most instances I would prefer to use round cellulose ester yarn such as cellulose acetate yarn on the packages 2. However, various other yarns of different compositions and cross sections may be processed in accordance with the present invention. For example, the yarns may be of Y or 0 cross section or other such special cross section, and the yarn. inaddition to being of cel: lulose acetate, may be polyester, polyamide, polyacrylonitrile or the like synthetics. The yarn in all instances, as is believed apparent from the description which has preceded, would be multi-filament having at least 30 filaments at a minimum. The yarn may be either twisted-or untwisted. In some instances a twist of 1 to 7 turns would be employed, although in general on carpet yarns zero twist is preferred.
Therefore, suitable yarn from packages 2 is drawn up from the packages by feed rolls which are driven at a certain predetermined;spe ed by, pulley 12.. The plurality ofyarn ends are simultaneously fed through a plurality of jets ,5, 5', 5", etc., .tl 1ese jets being of construction ale ready discussed in detail under Fig. 3, and have. supplied thereto a uniform and'cornmonsourceof air throughthe air header.
The plurality of yarnends are uniformly bulked and then taken up-by take-up rolls 6 and 7, said rolls being driven at a predetermined roller speed by means of drive 23. The bulked yarn from take-up rolls 6 and 7 then is packaged on the beam 8. In this manner not onlyis the yarn on a beam and thereby. ina much easier form for utilization inrug making, but since the yarn has been substantially uniformly bulked and held under comparable tension conditions throughout my process, the resultant yarn is more uniform than might be, experienced from making rugsfrom individual packages. A further understanding of my invention will behad from a consideration of the followingexamples:
Example I In accordancewith this example eight zero twist yarn supply packages containing 4800 denier, 400 filament, 0 section cellulose ester yarn are used. The yarn ends from the supply packages pass around the weighted idler roll 3 and then around feed roller 4 which is operating at a speed of 25 yd/min. From the feed roller the yarn ends are fed to the jets (5, 5, 5") where filtered air at a pressure of 20 p.s.i. gage bulks the yarn. After bulking in accordance with my invention, the yarn ends pass from the jetsto take-up roll 7 operating at a speed of 20 yd./min. In passing from the jet to the take-up rolls the filaments are severely tangled due to the turbulence of the air. The bulked, tangled yarn then proceeds to the wind-up on beam 8, which is accomplished by means of drum 9 driven at a surface speed of 20.5 yd./min. The speed of take-up roll 7an'ddrum 9 are directly correlated to the predetermined rate of speed of feed roll 4. The yarn thus produced in accordance with my invention comprised 5300 denier, 400 filament 0 section bulked rug yarn containing crunodal type yarn loops and a severely entangled filament structure which resists theremoval of the loops under normal processing of the yarn into a rug. When beam 8 was full it was used as the yarn supply to an eight needle tufting machine and swatches of rug material'were made. Examination and testing of these swatches indicated an excellent quality, uniform product had been obtained. 7
Example II Eight supply packages of regular section cellulose acetate, 2200 denier, filament, .75 Z twist yarn are used for the yarn supply. The feed roll '4 speed was 50 y.p.m. The yarn was treated in the jets at 25 p.s.i. air pressure and'then passed to the take-up rolls 6 and 7 which were set at a speed of 40 y.p.m. It then passed to the beam which was operated at 41 y.p.m. The treated yarn was characterized by a tangled loopy filament appearance and the-final denier was 2700.
ExampleIII 7 The yarn of Example H was treated in the same manner except that the rolls 6 and 7 were replaced by the friction rods of Fig. 2. The yarn was fed to the jets by the feed rolls at a speed of 50 y.p.m., From the jets it passed over and around the tension rods so that 270 of yarn wrap on the rods was obtained. The beam speed was 41 y.p.m. The'yarn' tension between the jets and the tension rods was 0-10' grams ineach yarn strand. The tension in each yarn strand'be'tween the rods and the beam was 200 to 250 grams.
The above examples are directed to a process and apparatus for the production of small rugs. However, by increasing the number of packages, say to 40 or 80 yarn packages, and increasing the roll widths, beam size and number of jets, any size beam may be produced. Fo'r example, in a rug machine requiring 800 ends of yarn, beams containing 80 ends of yarn each could be made up. That is, in Fig. 1 the number of threads, jets and the like would be increased so that beam 8 of Fig. 1 would have 80 ends wound thereon.
As described above, in my apparatus it is possible to vary the several roll speeds to give faster or slower speeds or more or less bulking, or more or less windup tension, as may be desired. The denier of the yarn may be varied for any particular end use. While I have described in particular the preparation of beams of bulked yarn for use in carpet manufacture, and the process and apparatus of the present invention are particularly useful for this purpose, my invention is not limited to producing beamed yarn for only this purpose. For example, 1000 denier beamed yarn produced in accordance with the present invention may be used for chenille bed spreads. Or, in a similar manner, 300 denier yarn may be processed to obtain warp beams for use in woven fabric looms.
As apparent when processing different denier yarns and the like, the particular air pressure used and other details of operation may be varied. While in the above examples air pressures of lbs/sq. in. gage have been mentioned, the air pressure may vary from say 8 lbs./ sq. in. to 50 lbs/sq. in. The jet of Fig. 3 is designed so that in the area of the orifice and venturi throat the air velocity is sonic or supersonic.
The yarn prior to processing in my apparatus is preferably treated with a yarn treating agent having a high electrical resistivity such that the generation of static electricity on the yarn is not appreciably inhibited, which static charge aids in causing filament separation in the bulking jet. Said agent also has the property of causing the yarnto have a high scroop value or ratio of static friction to dynamic friction, said scroop being of material assistance in preventing the removal of the yarn loops and entanglement in subsequent processing under tension of the yarn.
A valuable feature of my process and apparatus is that I am able to bulk or loft zero twist yarn and package it without imparting twist thereto. Such processing of zero twist yarn is specifically illustrated in Example I hereof. In such operations on zero twist yarn, the speed is generally kept below 50 yds/min. and the air pressure below 50 lbs./ sq. in.
While I prefer in many instances to process zero twist yarn, my process and apparatus will also satisfactorily function on pretwisted yarn. For example, the yarn on packages 2, 2', etc. may have, for example, from /5 to 7 or 8 turns therein.
It is apparent from the foregoing description that an improved method and apparatus have been provided whereby bulk yarn of improved uniformity may be obtained o'n beams, thereby rendering bulk or lofted yarn more useful in the textile trade inasmuch as said beams are more readily adapted to use in weaving processes.
I claim:
1. The process for the manufacture of beamed, bulked yarn particularly suitable for carpet manufacture which comprises providing a plurality of packages of yarn from which the yarn is delivered to feed rolls, said yarn being characterized by being continuous, multi-filament yarn of'varying denier from 3 to 20 denier and having fiber distribution as follows: l0%--3 D/F, 20%5 D/F, 40%-8 D/F, 15%l2 D/F, 10%l6 D/F, 5%--20 D/F, passing said yarn of varying denier through a plurality of air jets, said plurality of jets being supplied by a common air supply whereby the ends are subjected to substantiallythe same air treatment and are thereby bulked, taking the bulked sheet of ends away from said jets by means of take-up rolls operating at a lower speed than the speed of the first-mentioned rolls, passing the bulked .yarn thus taken up on-the last mentioned rolls to a rotating beam, said passage being through means where- 'by the bulk yarn is uniformly positioned on said beam, and rotating the beam containing the bulked yarn by drive means which is correlated to the rotation of the other rolls aforementioned.
2. The process for manufactming beamed, bulked yarn which comprises gathering from a plurality of separate packages a sheet of continuous, multi-filament yarn ends, conducting these ends around a single elongated feed roller for all of said ends rotating at a predetermined speed, passing said sheet of ends from the single elongated feed roller through a plurality of air jets, said plurality of jets being supplied by a common air supply whereby the ends are subjected to substantially the same air treatment and are thereby bulked, taking the bulked sheet of ends away from said jets by means of a single elongated take-up roll operating at a lower speed than the speed of the. first-mentioned roll, passing said bulked yarn to a rotating beam of a length sufiicient to receive all of said ends, said passage being through means whereby the bulk yarn is uniformly positioned on said beam, and rotating the beam containing the bulk yarn by drive means which is correlated to the rotation of the other rolls aforementioned.
3. The process of manufacturing beamed bulked yarn suitable for rug production which comprises feeding at least 8 ends of zero twist yarn of 0 section filaments from separate packages onto -a single feed roll which receives all of said ends, feeding the yarn aforesaid at the same rate of speed for all the yarn through a plurality of air bulking jets operating from a common air supply, taking up the bulked yarn from said jets onto a single elongated take-up roll at the same rate of speed for all the yarn, delivering the bulked yarn from the take-up roll to a beam, and rotating the beam and rolls by means of a common and correlated drive whereby the take-up roll is operated at a slower speed than the feed roll and the bulked yarn is wound on the beam in a uniform manner.
4. An apparatus for producing beamed, bulked yarn which comprises means for feeding yarn ends from a plurality of packages to a single elongated feed roll for all of said ends, a plurality of air jets provided with a common air supply positioned between said feed roll and a single elongated take-up roll for all of said ends, said take-up roll being adapted to deliver bulk yarn through distribution means to a beam whereby the bulked yarn is deposited uniformly on said beam, and driving means interconnected and associated with all of said rolls and said beam so that the take-up rolls may be rotated at a slower speed than both the feed rolls and the beam.
5. A process in accordance with claim 2 wherein said drive means is further characterized by the maintenance of a constant linear surface speed ratio between the aforementioned rolls and rotating beam.
6. In .a process for manufacturing beamed, bulked yarn which comprises gathering from a plurality of separate pack-ages a sheet of continuous, multi-filament yarn ends, conducting these ends around a feed roller means for all of said ends, said roller means rotating at a pre- '7 determined speed; passing-said sheetof" ends iroxnthe References Cited inthe fiie of this patent feed roller means through a plurality of airjets, said plu- UNITEDSmATES PATENIfS rality of jets being supplied by a common air supply whereby the endslere subjected -to substantially the-same ir e mentwr nd e th reby, h l d h i mpm m n feature which comprises taking the bulked sheet of ends away from the jets by s nubbin g them over a pair ofed- I V V o justable tension rolls-to maintain-relatively lowtension 21671179421 Q Mar! 1954 on the idowns tream side of the'jets, and then passing 7 2,829,420 A 1958 said bulked yarn to a rotatingbeam of a length sufficient l0 2,852,906 3 9 1958 to receive all of said ends, said passage being through v means whereby the bulked'yarn is under tensibn which v FOREIGN PATENTS v is uniform mm end :to end;*androtatingthebeam con- 161,9 ustr i ---t-:,--;-- F .,1955 taining the bulked yarn by drive means which is cor- ,215w Germany Oct. 8, 19571 relatedto the rotation of the roll means aforementioned. 15
5 2,224,565 Bradshaw et i',
2,439, 03.94 Q e, sew-t 23329- is. t 1;
'--s-,-- -.-"D. c-, 0 -1- Ap 9 3. Apr. 15 1952 2.031512. Ka ilischo-r-Q-a-t-er. Apr. 14,1936
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Cited By (15)

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Publication number Priority date Publication date Assignee Title
US3046632A (en) * 1960-02-23 1962-07-31 Tsutsumi Kikuichi Method and apparatus for producing wool-like yarn from synthetic fibers
US3108427A (en) * 1959-07-17 1963-10-29 Us Rubber Co Apparatus and method for producing a plurality of ply yarns
US3109278A (en) * 1960-08-19 1963-11-05 Du Pont Multilobal textile filaments having controlled uniform twist and fabrics prepared therefrom
US3188713A (en) * 1963-05-06 1965-06-15 Eastman Kodak Co Apparatus for processing crosssection yarn
US3296677A (en) * 1963-05-20 1967-01-10 Eastman Kodak Co Crimping apparatus and process
US3325906A (en) * 1965-02-10 1967-06-20 Du Pont Process and apparatus for conveying continuous filaments
US3404523A (en) * 1965-12-01 1968-10-08 Vyzk Ustav Bavinarsky Device for guiding yarn
JPS4844549A (en) * 1970-04-06 1973-06-26
US4095319A (en) * 1977-01-26 1978-06-20 Eastman Kodak Company Yarn fracturing and entangling jet
US4525905A (en) * 1981-07-18 1985-07-02 Karl Mayer Textilmaschinenfabrik Gmbh Apparatus for beaming elastic threads
US4669158A (en) * 1983-10-27 1987-06-02 Val Lesina S.P.A. Method for preparing warp wound on beams, starting from a series of continuous, partially-drafted thermoplastic yarns
US6073434A (en) * 1999-12-27 2000-06-13 Williams Specialty Company Multiple yarn end pneumatic splicer
US6107218A (en) * 1998-05-11 2000-08-22 Chatham Incorporated Chenille yarn for high speed weaving applications and improved product wear performance
US6588192B1 (en) 1998-05-11 2003-07-08 Chatham, Inc. Methods of making new chenille yarns for high speed weaving applications and improved product wear performance
US20030233744A1 (en) * 2002-06-03 2003-12-25 Hunter Douglas Inc. Beam winding apparatus

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US2037512A (en) * 1933-07-11 1936-04-14 Kahlisch Gustav Method of producing cross-wound warp beams and apparatus therefor
US2224665A (en) * 1939-04-22 1940-12-10 Du Pont Production of rayon structures
US2439039A (en) * 1944-09-26 1948-04-06 American Viscose Corp Process of producing medullated artificial filaments
DE816215C (en) * 1949-03-29 1951-10-08 Algemeene Kunstvezel Mij N V Device for the production of mats or webs from glass fibers or similar fibers
US2593320A (en) * 1950-07-07 1952-04-15 Us Rubber Co Apparatus for heat-treating nylon yarn or cord
US2671942A (en) * 1949-02-09 1954-03-16 Electric Construction Co Electrical drive for textile machines
US2829420A (en) * 1953-05-12 1958-04-08 American Enka Corp Method and apparatus for bulking yarn
US2852906A (en) * 1951-12-14 1958-09-23 Du Pont Method and apparatus for producing bulky continuous filament yarn

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Publication number Priority date Publication date Assignee Title
US2037512A (en) * 1933-07-11 1936-04-14 Kahlisch Gustav Method of producing cross-wound warp beams and apparatus therefor
US2224665A (en) * 1939-04-22 1940-12-10 Du Pont Production of rayon structures
US2439039A (en) * 1944-09-26 1948-04-06 American Viscose Corp Process of producing medullated artificial filaments
US2671942A (en) * 1949-02-09 1954-03-16 Electric Construction Co Electrical drive for textile machines
DE816215C (en) * 1949-03-29 1951-10-08 Algemeene Kunstvezel Mij N V Device for the production of mats or webs from glass fibers or similar fibers
US2593320A (en) * 1950-07-07 1952-04-15 Us Rubber Co Apparatus for heat-treating nylon yarn or cord
US2852906A (en) * 1951-12-14 1958-09-23 Du Pont Method and apparatus for producing bulky continuous filament yarn
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Cited By (27)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3108427A (en) * 1959-07-17 1963-10-29 Us Rubber Co Apparatus and method for producing a plurality of ply yarns
US3046632A (en) * 1960-02-23 1962-07-31 Tsutsumi Kikuichi Method and apparatus for producing wool-like yarn from synthetic fibers
US3109278A (en) * 1960-08-19 1963-11-05 Du Pont Multilobal textile filaments having controlled uniform twist and fabrics prepared therefrom
US3188713A (en) * 1963-05-06 1965-06-15 Eastman Kodak Co Apparatus for processing crosssection yarn
US3296677A (en) * 1963-05-20 1967-01-10 Eastman Kodak Co Crimping apparatus and process
US3325906A (en) * 1965-02-10 1967-06-20 Du Pont Process and apparatus for conveying continuous filaments
US3404523A (en) * 1965-12-01 1968-10-08 Vyzk Ustav Bavinarsky Device for guiding yarn
JPS4844549A (en) * 1970-04-06 1973-06-26
JPS5421456B2 (en) * 1970-04-06 1979-07-31
US4095319A (en) * 1977-01-26 1978-06-20 Eastman Kodak Company Yarn fracturing and entangling jet
US4525905A (en) * 1981-07-18 1985-07-02 Karl Mayer Textilmaschinenfabrik Gmbh Apparatus for beaming elastic threads
US4669158A (en) * 1983-10-27 1987-06-02 Val Lesina S.P.A. Method for preparing warp wound on beams, starting from a series of continuous, partially-drafted thermoplastic yarns
US6588192B1 (en) 1998-05-11 2003-07-08 Chatham, Inc. Methods of making new chenille yarns for high speed weaving applications and improved product wear performance
US6107218A (en) * 1998-05-11 2000-08-22 Chatham Incorporated Chenille yarn for high speed weaving applications and improved product wear performance
US6073434A (en) * 1999-12-27 2000-06-13 Williams Specialty Company Multiple yarn end pneumatic splicer
US20030233744A1 (en) * 2002-06-03 2003-12-25 Hunter Douglas Inc. Beam winding apparatus
US7017244B2 (en) * 2002-06-03 2006-03-28 Hunter Douglas Inc. Beam winding apparatus
US20060143881A1 (en) * 2002-06-03 2006-07-06 Hunter Douglas Inc. Beam winding apparatus
US20060277730A1 (en) * 2002-06-03 2006-12-14 Hunter Douglas Inc. Beam winding apparatus
US20060277729A1 (en) * 2002-06-03 2006-12-14 Hunter Douglas Inc. Beam winding apparatus with beam switching turntable
US20060277732A1 (en) * 2002-06-03 2006-12-14 Hunter Douglas Inc. Beam winder with yarn shrink system
US20070000108A1 (en) * 2002-06-03 2007-01-04 Hunter Douglas Inc. Method of setting up a beam winder
US7178211B2 (en) 2002-06-03 2007-02-20 Hunter Douglas Inc. Beam winding apparatus with beam switching turntable
US7181816B2 (en) 2002-06-03 2007-02-27 Hunter Douglas Inc. Beam winder with yarn shrink system
US7234212B2 (en) 2002-06-03 2007-06-26 Hunter Douglas Inc. Method of winding a beam
US7234213B2 (en) 2002-06-03 2007-06-26 Hunter Douglas Inc. Beam winding apparatus
US7260873B2 (en) 2002-06-03 2007-08-28 Hunter Douglas Inc. Method of setting up a beam winder

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