Search Images Maps Play YouTube News Gmail Drive More »
Sign in
Screen reader users: click this link for accessible mode. Accessible mode has the same essential features but works better with your reader.

Patents

  1. Advanced Patent Search
Publication numberUS3740282 A
Publication typeGrant
Publication dateJun 19, 1973
Filing dateFeb 16, 1971
Priority dateFeb 16, 1971
Publication numberUS 3740282 A, US 3740282A, US-A-3740282, US3740282 A, US3740282A
InventorsG Watson
Original AssigneeCelanese Corp
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Process for making artificial leather from lapped fibrous structures
US 3740282 A
Abstract  available in
Images(2)
Previous page
Next page
Claims  available in
Description  (OCR text may contain errors)

June 19, 1973 G. A. WATSON 3,740,282 PROCESS FOR MAKING ARTIFICIAL LEATHER FROM LAPPED FIBROUS STRUCTURES Original Filed Jan. 5. 196 2 Sheets-Sheet l Original Filed Jan. 5. 1967 June 19, 1973 G WATSON 3,740,282

PROCESS FOR MAKING ARTIFICIAL LEATHER FROM LAPPED FIBROU-S STRUCTURES 2 Sheets-Sheet 2 United States Patent @fice 3,740,282 Patented June 19, 1973 3,740,282 PROCESS FOR MAKING ARTIFICIAL LEATHER FROM LAPPED FIBROUS STRUCTURES George A. Watson, Charlotte, N.C., assignor to Celanese Corporation, New York, N.Y.

Original application Jan. 3, 1967, Ser. No. 606,982, now abandoned. Divided and this application Feb. 16, 1971, Ser. No. 115,703

Int. Cl. B321) 31/12, /08

US. Cl. 156--148 1 Claim ABSTRACT OF THE DISCLOSURE Making stratified lapped fibrous structures such as cross-lapped webs, or yarns, which have layers of different fibers by, for example, feeding a web having sideby-side bands of different fibers to a cross-lapping device.

This application is a divisional of United States application Ser. No. 606,982 filed Jan. 3, 1967, now abandoned.

This invention relates to the production of lapped fibrous structures.

In accordance with one aspect of this invention, I produce lapped structures which, in cross-section, have a predetermined non-uniform distribution of fiber-s by providing a fibrous web having a predetermined non-uniform distribution of the fibers across the width of the web, and lapping the web. Surprisingly, I have found, for example, that by otherwise ordinary cross-lapping techniques I can produce cross-lapped batting, relatively thin in relation to its surface area, having one surface of one fiber and its other surface of a different fiber, by feeding a thin web made of side-by-side relatively fiat zones of the two fibers.

Certain embodiments of this invention are illustrated in the accompanying drawings, in which:

FIG. 1 is a top view of a cross-laying operation;

FIG. 2 is a side view of the operation shown in FIG. 1;

FIG. 3 is a schematic perspective view of a device for making a cross-lapped structure from staple fibers;

FIG. 4 is a schematic perspective view of the spreading and cross-lapping of a tow band;

FIG. 5 is a schematic perspective view of the formation of a yarn of predetermined fiber distribution; and

*FIG. 6 is a schematic perspective view of a device for making a crimped tow band having a predetermined nonuniform distribution of fibers.

The effect may be understood by a consideration of FIGS. 1 and 2 showing a web 11 of three side-by-side layers of different fibers (labelled A, B, and C) being fed to a cross-lapping zone 12 where they are traversed back and forth by a head 13 over an apron 14 while the resulting cross-lapped batting 16 is taken off continuously in a direction (indicated by the arrow) transverse to the traversing direction. In the usual cross-lapping process, producing a batting whose thickness is made up of several layers (e.g. 6 to 12 or more layers) of the fibrous web, I have observed that while the initially formed layer lies relatively flat on the apron, after the process has been run ning for a short time, each new layer is laid down at what is, in effect, a slight angle (greatly exaggerated in FIG. 2) to the upper and lower faces of the batting with one edge 18 of the web appearing at the bottom face of the batting and the opposite edge 19 of the web appearing at the top face of the same batting, as shown in simplified form in FIG. 2. By using a plurality of parallel wide bands side-by-side in the web, I thus form a corresponding series of thin parallel strata in the batting.

In another aspect, helical lapping is used, with one edge of the banded web forming the outside surface of the lapped structure and the opposite edge being buried in the interior of the structure. In a preferred form of this aspect of the invention, the helical lapping is employed for the production of yarns or other funicular structures (such as slivers), which, in transverse cross-section, have a predetermined radially non-uniform distribution of the different fibers. In this way, yarns having a core which is predominantly of one fiber and a covering which is predominantly of a different fiber may be obtained. The relative proportions of the two fibers may be varied widely so as to vary the characteristics of the final sliver or yarn product; thus, the ratio of the proportion of that fiber which predominates in the surface to the proportion of the fiber which predominates in the core may be in the range of 99:1 to 1:99, e.g. 5:95, 10:90, 30:70, 50:50, :30, :10 or :5.

The reference herein to different fibers is intended to include fibers differing in any attribute. Thus, the fibers may differ only in denier, or in cross-section, or in degree of crimp, or in staple length, or in color, or in the material of which they are made. For certain purposes, e.g. for the preparation of battings having different resistances to bending in opposite directions, the fibers should differ in stiffness; for example, one face of the batting may be composed predominantly of fibers of greater stiffness than those of the other face. Such increased stiffness may be attained, for example, by using fibers of heavier denier or fibers of non-circular cross-section (e.g. of cruciform, triangular, trilobal, H or other cross-section while fibers of circular cross-section may predominate at the other face), or fibers of inherently stiffer material (e.g. of polyethylene terphthalate which is stifier than nylon-6 or nylon-66). The different fibers may be blends of fibers; for example, one fiber blend may differ from the other only in the proportions of its components; thus, one band of the web may contain an 80:20 blend of two fibers and the adjacent band of different fibers may be composed of a 50:50 blend of the same two fibers.

The web used in making the lapped structure may be made up of staple fibers or it may be a web of continuous filaments, such as a web produced. from a crimped continuous filament tow band by a continuous crimp-deregistering and air-spreading process.

Typical staple fiber webs may be produced on conventional web-forming devices such as cards, Garnetts or air lay machines such as Rando Webber (see Man- Made Textile Encyclopedia, edited by J. J. Press, pub. 1956 by Text Book Publishers, Inc., pp. 484-5). The fibers may be crimped or uncrimped and may, for example, have the length of conventional staple fibers, e.g. about /2 to 6 inches. The different types of staple fibers may be fed in side-by-side bands of loose fibers to the carding device, thrown loosely into segmented feed hoppers. Two laps of different staple fibers may be formed on a picker and these laps fed side-by-side to the web-forming device. A wide picker lap of one fiber may be split lengthwise to form a number of narrower laps, each of which can be fed to the web-forming device sideby-side with one or more similarly produced narrow laps of different fibers. When an air laying machine is employed, it may be divided lengthwise by thin baffles which will serve to substantially segregate the different fibers during their simultaneous passage through the machine.

Webs of continuous filaments having bands of different fibers may be produced by laying a plurality of multifilament tows of the different fibers side-by-side in contact with each other and, preferably, treating the assembly to cause the edges of each of these tows to adhere to the adjacent tow so that the assembly can be handled as a single large tow (containing, for example, about 5000 to 1,000,000 continuous filaments). One techinque for effecting such adheres is to feed the smaller tow bands together to a crimping device such as a stulfing box crimper of conventional type where not only are the tow bands crimped but the fibers at their adjacent edges are overlapped and intermingled sufiiciently to cause the bands to adhere together. In the manufacture of a particularly suitable type of cross-lapped structure, the resulting crimped tow band, having crimps in Widthwise registry (i.e. in which the crimped fibers, which run lengthwise of the band, have their aligned peaks and valleys extending as ridges and troughs transversely of the band) is subjected to a crimp-deregistering operation followed by a spreading operation, as described, for example, in the French Pat. N0. 1,418,403 (South African 64/5473) to produce a lightweight web which is then cross-lapped to form the batting. In a typical light-weight web produced in this manner, all the continuous filaments run in the same general direction, lengthwise of the web. However, when one does not look at the whole of a long length of any particular filament, but looks instead at the individual crimps thereof, it will be seen that most portions of the filament do not run in this general lengthwise direction but instead zigzag back and forth across such general direction. The amplitude of the crimps is such that, for any particular filament, the portion of the crimp at one side (hereafter termed the crest of the crimp) overlaps one or more neighboring filaments while the portion of the crimp at the other side (hereafter termed the valley of the crimp) overlaps one or more of its neighboring filaments on said other side. This overlap helps to give the Webs their cohesiveness. For example, the filaments in the web may have a crimp whose amplitude (from a median line running in the same direction as the filament) is in the range of about V to 7 inch, said amplitude being measured from said median line to the top of a crest, or to the bottomof a valley. Since there may, for example, be several hundred filaments per inch of web width and since the crimps are not in registry there will be considerable overlapping of filaments in the web.

When one turns from an examination of the crimps and takes a somewhat larger, though still relatively short, view of the portion of any particular filament which contains several crimps, and which may for example be /2 inch to several inches long, it will be found that these portions are not perfectly parallel to the longitudinal direction of the web, but make small angles therewith, which angles change in direction and magnitude along the length of the filament; generally these angles are less than 20, although for very short portions (e.g. /2 inch long) the angle may be larger at times.

It is believed that the overlapping of the crimps and the overlapping due to the presence of the angularly disposed short portions, just described, contribute to the cohesiveness of the web so that, despite its fineness, it can be readily handled as a unitary structure. The degree to which the individual filaments meander by virtue of the presence of said crimps and angularly disposed short portions is not, however, very great; typically, the ratio of the straightened lengths of the individual filaments to the lengths of the same filaments in the web is less than about l /zzl and, preferably, greater than 1.1:1, e.g. about 1.221 to 1.4:1. The ratio may be measured by cutting a predetermined length of the web, removing the individual filaments of the cut portion and measuring their lengths while under a tension just sufficient to remove the crimp; the results are then expressed as the ratio between the measured lengths of the individual filaments and said predetermined cut length.

It is also within the scope of the invention to use a qvmb tion of q ti usus an staple fib s. For xample, to a single cross-lapping device there may be fed a coherent web of continuous filaments, as described above, alongside of (or partially or completely overlapped by) a web of staple fibers.

Typically, the fibers will have a denier within the range of about 1 to 25. When crimped they may have, for example, about 5 to 50 or more (e.g. about 8 to 16) crimps per inch. As fiber materials, there may be used such substances as polyesters (e.g. the terephthalate ester of ethylene glycol or other glycol such as dimethylol cyclohexane), linear superpolyamides (such as nylon-6, nylon 6,6, nylon-4, nylon1l, or hexamethylene terephthalamide), melt-blended polyamide-polyester combinations, acrylics such as polyacrylonitrile and acrylonitrile copolymers, modacrylics, olefinic polymers and copolymers, e.g. isotactic polypropylene, rubbery spandex, rubber, organic derivatives of cellulose, such as esters or ethers, for example secondary cellulose acetate, cellulose triacetate, cellulose propionate, cellulose acetate propionate, or the like, rayon (regenerated cellulose), conjugate-spun (e.g. bi-component) fibers such as fibers containing parallel adherent components of nylon and polyester or of cellulose triacetate and saponified or unsaponified cellulose acetate, glass, metal, metal foil laminated to plastic such as cellulose acetate or polyethylene terephthalate. Cardable, garnettable natural fibers such as cotton, wool, silk, linen, or ramine or other fibers or filamentary material capable of forming a cohesive web may also be used.

As indicated previously, for some purposes each band of fibers may be composed of a blend of fibers. Thus, in the manufacture of a dense batting such as is used as a base in artificial leather, it is desirable to blend a shrinkable fiber with a fiber stable under the conditions of treatment. For example, fibers which shrink when heat is subsequently applied to the batting (e.g. fibers of polypropylene or polyvinyl chloride, or cold drawn polyester fibers) may be intimately blended with fibers (such as heat-set polyester fibers which are stable) under the same heat-treatment.

The batting or the individual webs may be given other treatments to improve the coherence of the batting or change its characteristics. The batting, or the individual Webs, may be sprayed with adhesive, the batting may be quilted by stitching, treated to adhere its fibers (as by heat-sealing or solvent-sealing) along a predetermined pattern, needled, calendared, saturated or powder-bonded. For the manufacture of artificial leather, needling (preferably followed by a heat-shrinking treatment, particularly when using a fiber blend as described above) is a desirable treatment. In the needling operation, the batting is generally passed through a needle loom equipped with the usual barbed needles which reciprocate perpendicularly to the face of the batting and serve to move portions of the filaments from each web layer upward or downward so that these portions intermingle with filaments of neighboring webs. The batting is advantageously given several passes through the needle loom and is turned over after each pass. Because of the crimp in the continuous filaments, the filaments can often undergo considerable extension into adjacent layers without exerting a substantial contracting effect on the whole batting. The needle looms used may be those commercially employed in the needle punching of staple fiber battings.

The batting may be given one or more coatings. Thus, for the manufacture of artificial leather, the needled batting, which may for example be .025" to .060" thick, may be impregnated with a rubbery material, preferably a synthetic rubber such as a rubbery polyurethane, which may be made from a diisocyanate and a polyester or polyether; a polymer of a butadiene and another monomer, e.g. acrylonitrile, styrene, vinyl pyridine, methyl methacrylate, or a homopolymer of butadiene or isoprene or chloroprene; or a rubbery ethylene-propylene copolymer, etc. Preferably, the rubbery polymer is deposited in the needled structure in such a fashion that the resulting material remains porous, preferably microporous. This may be done in any known manner, as by the use of blowing or foam-forming agents or by the use of rubber latices followed by coagulation, e.g. with an aqueous solution of an acid such as acetic acid or of a salt as calcium chloride, or by inclusion of a leachable material such as finely divided sodium chloride which is later extracted from the deposited polymer with water. Advantageously, the rubber is vulcanized as by the inclusion of suitable known cross-linking agents therein, ffollowed by curing. Thereafter, a thin coating 2-40 mils, e.g. 8 mils, thick, of a tough polymer such as polyethyl acrylate, polyvinyl chloride, or a polyurethane or the like, is applied.

The invention finds its greatest utility in the production of battings or other cross-lapped structures made up of 5 or more cross-lapped layers (e.g. 3 to 40 layers). Such multilayered structures can be produced, as is well known, by controlling the speed of lateral movement of the cross-lapped structure in relation to the frequency of traverse and the width of the web fed to the crosslapping zone. Thus, to produce a structure made up of n layers, the cross-lapped structure will be moved laterally, and continuously, during each back and forth traverse cycle, a distance equal to W/n where W is equal to the width of the web fed to the cross-lapping zone. Generally, the webs will have widths of the order of about 24 to 180 inches.

The following examples are given to illustrate this invention further:

EXAMPLE 1 In this example, there is employed a Saco-Lowell card 26 (FIG. 3) fitted with garnett clothing and comprising a driven endless feed belt 27 to which staple fibers are continuously supply (e.g. as a uniform sheet such as a lap produced by a picker device), a driven rotating cylinder 28 carrying toothed garnett cloth, and a device 29 for removing a web 31 (shown in broken lines) of aligned staple fibers from the cylinder 28 and for feeding this web to a cross-lapping device of conventional construction (e.g. a cross-laying machine) of the camel back type having an upwardly inclined driven belt 32 for transporting the web to another driven belt 33 from which the web passes to an oscillating structure 34 pivoted at the top and having a pair of driven belts 36, 37 engaging opposite faces of the web and serving to transport the web to a longitudinally moving apron 38 (a driven endless belt) on which the Web is traversed back and forth by the movement of the oscillating structure.

Over /3 of the width of the feed belt 27 there are fed white staple fibers, while over the remaining there are fed blue staple fibers, so that there are two distinct bands of fibers side-by-side on that belt. Both the white and the colored fibers may be be, for example, cellulose acetate staple fibers of 3 d.p.f. and 1 /2 inch fiber length. The resulting web taken off the cylinder has substantially the same two bands as the material supplied to the cylinder, while the final cross-lapped batting is blue on one side and white on the other with a distinct interface between the blue layer and the white layer. In one embodiment, the web 31 may have a weight of about /2 ounce per square yard, while the cross-lapped batting 39 may have a weight of about six ounces per square yard (thus, the batting cross-section is made up of about 12 thicknesses of the web); such a web may be made by adjusting the rate of movement of the apron in relation to the frequency of traverse so that the apron moves of the width of the web for each back and forth traverse cycle.

ament (d.p.f.) across its witdh is produced by feeding five different sub-tows, here designated, from left to right,

as V, W, X, Y, and Z (of uncrimped continuous filaments of undrawn polyethylene terephthalate of circular filament cross-section) side-by-side through guides 40 and around the concave side of a curved bar 41 (of circular cross-section) which serves to converge the sub-tows, then through a conventional finish, in tank 42, over another bar 43, to a drawing section 44 having two pairs of positively driven rolls (pair 46 and pair 47) the second pair (47) being driven at a multiple of the speed of the first pair (46) (e.g. about 4 times the surface speed of the first pair). The reach of tow between the pairs of rolls passes over a convergence guide 48 whose toW- engaging surface is displaced above or below the plane line joining the nips of the pairs of rolls 46, 47; the yarnengaging surface of this guide 48 is concave (when viewed in a cross-section taken in a vertical plane transverse to the general path of the tow) so that the drawing tension exerted by the roll pair 47 forces the sub-tows together in controlled manner, giving a controlled intermingling of fibers at the edges of adjacent sub-tows. The drawn tow band is then fed to a conventional stuffer box crimper, Whose exit and entrance are each 1 /2 inches wide, where it is mechanically crimped, and it is then baled.

In one specific example nine undrawn sub-tows are used, all of the same total denier, having the following undrawn deniers per filament: for the three sub-tows closest to one edge of the two band, 6 d.p.f.; for the three sub-tows making up the center portion of the tow band, 12 d.p.f.; and for the three sub-tows closest to the other edge of the tow band, 20 d.p.f.; so that in the drawn tow band having a total denier of, for example, 128,000, there are side-by-side bands (somewhat intermingled at the edges of said bands) of about 1 /2, 3 and] 5 d.p.f. filaments.

The resulting crimped tow band, in which the crimps are in registry, extending across the width of the tow band, (and having, for example, 10 crimps per inch and 30% crimp), is passed through a tow opening and airspreading system as illustrated in FIG. 4 of the drawing (and of the type disclosed in French Pat. 1,418,403) to form a diaphanous spread web 49 which is continuously delivered to a cross-lapping apparatus comprising a reciprocating cross-laying chute 50 (provided at the top) and an apron, which is preferably a continuously endless belt 50a on which the cross-lapped batting forms. The rate of feed of the web, the frequency of reciprocation of the chute and the speed of the belt are correlated so that there is produced a batting weighing about 14 ounces per square yard. This batting is then passed through a needlepunching machine of conventional design in which it is subjected to a series of needles rapidly reciprocated perpendicularly to the face of the batting so as to bring fibers from one layer of the web into adjacent layers in a direction perpendicular to said face. The batting is passed through the needling zone a number of times, and is turned over at each pass, until a total of 800 punches per square inch has been made from each side of the batting. The resulting needled web has substantially greater resistance to bending in one direction than in the opposite direction.

The needled batt is immersed in a tank contining butyl rubber latex plus curing agents. The batt is removed from the tank by squeeze rolls Whose pressure is adjusted to allow the batt to pick up 30% of the rubber. The impregnated batt is treated to coagulate the latex and is then passed through a curing oven. The firmly bound microporous batt is then sueded by a wide endless belt made of grit sandpaper. The sueding of both sides of the batt results in an even thickness. That face of the batt where the convex bending resistance is higher is then coated with a solution of polyurethane, of known type, to deposit a microporous abrasion-resistant coating thereon.

In a typical tow opening and spreading system shown in FIG. 4, the tow band 51 is drawn from the bale 52 through a banding jet 53 in which air is blown at the tow so that it emerges as a flattened band of a width of, for

example, 8 inches. This band passes around adjustable stationary tensioning bars 54 which help to smooth and uniformly pre-tension it, then into the nip between a pair of rubber-surfaced rolls 55, 56 driven at a constant speed and horizontally to the nip between a rubber-surfaced roll 57 and a driven threaded steel roll 58. The tow band then passes through a pair of air spreaders 59 and 61 in each of which air is blown transversely at the tow band so that it is spread to a width of say 50 inches, in two stages. Before entering the second spreader 61 and after leaving that spreader, the tow band makes an S-wrap about a pair of rolls 62, 63 and a second pair of rolls 64, 66. The tow then passes, in a shallow catenary path to a third pair of rolls 67, 68, at the head of the chute 50. The lower roll of each of the pairs of rolls herein described is positively driven while the corresponding upper roll is pressed downwardly, by any suitable loading device, so that each upper roll is driven by frictional contact with the tow on the lower roll of the pair. Rolls 56, 63, and 66 are driven at about the same linear surface speed, while roll 58 is driven at a linear surface speed about 1 /2 times that of these rolls.

EXAMPLE 3 A series of four different fiber materials are supplied from four troughs, situated side-by-side over a continuously driven supply belt (such as belt 27 of FIG. 3). The four materials in the respective troughs, reading from left to right, are:

(a) A uniform blend of 50% 1 d.p.f. drawn polyethylene terephthalate (p.e.t.) fibers of 1 /2 inch staple length and 50% 1 d.p.f. drawn polypropylene heat-shrinkable fibers of 1 /2 inch staple length;

'(b) A uniform blend of 40% of 2 d.p.f. fibers of the same polyester and 60% 2 d.p.f. heat-shrinkable fibers of the same polypropylene;

(c) A uniform blend of 30% of 3 d.p.f. fibers of the same polyester and 70% of 1 d.p.f. heat-shrinkable fibers of the same polypropylene; and

(d) 100% of 4 d.p.f. heat-shrinkable fibers of polyvinyl chloride of 1 /2 inch staple length, like all the others.

All the above filaments are of cricular cross-section.

The materials are fed at equal rates from each trough to the continuously driven belt 27, forming four distinct fiber bands of equal width on that belt. These bands pass continuously to a card of the type used in Example 1 to form a web which is then fed to a cross-lapper as in that example, to give a batting whose thickness is made up of 14 layers of the web and weighs about 15 ounces per square yard. Alternatively, instead of supplying these four different fiber materials to the troughs, each of these materials may be formed separately into a picker lap, which may be split into narrow bands or sub-laps and the four different sub-laps may be supplied as such to the belt 27.

The cross-lapped batting is then needled as in Example 2 using a total of 1500 punches per square inch from each side of the batting and then heated treated to cause shrinkage of the heat-shrinkable fibers, as by boiling in water.

The needled batting is then impregnated with a foamable polyurethane-forming composition of known type, such as that disclosed in Tischbein US. Pat. 2,993,813 of July 25, 1961, and then cured, to form a porous rubbery polyurethane in the fibrous structure, and a thin coating of said porous rubbery material above the fibrous structure. The impregnation is controlled to give a product containing about 40% of the polyurethane, based on the total weight. There is then applied, to that face of the impregnated porous product where the convex bending resistance is higher, a thin coating of pigmented polyacrylate of high molecular weight; this may be done by applying a lacquer comprising polyethyl acrylate in a volatile organic solvent, or an aqueous dispersion containing 45% of said polymer, followed by drying.

The face of the batt where the convex bending resistance is higher can be determined by comparing the resistance of the batt to bending first in a direction to make one face convex (and the other face correspondingly concave) and then in the direction to make the other face convex.

The preferred polyhydroxy compound to be used in the formation of the polyurethane is a low molecular weight polymer having hydroxyl end groups and containing three poly(tetramethylene ether) blocks per molecule; this low molecular weight polymer may be made by reacting 3 moles of dry poly(tetramethylene ether) glycol having an average molecular weight of about 1000 with two moles of 2,4-tolylene diisocyanate in a manner well known to the art.

EXAMPLE 4 This example illustrates the production of covered or core yarns. In the manner described in Example 1, there is produced a web 71 comprising a narrow longitudinal band 72 of one fiber and a much wider area 73 of another fiber on a driven endless belt 74 tilted upward at a small angle. Resting on the belt 74 is a driven roll-up roll 76 rotating in the direction shown by the arrow around its axis 77 and driven (as through a belt and pulley arrangement 78) by a motor 79. The axis of the roll 76 is oblique (i.e. neither transverse nor parallel) to the direction of movement of the web 71, making an angle or, preferably an angle of or less, to the direction of movement of the web. The rolled-up fibers are continuously drawn off in the general direction of the axis of the roll-up roll 76 by the action of a driven rotating sliver drum 81 of the conventional type. In the embodiment shown in FIG. 5, substantially all the fibers marked B (of band 72) will be on the outside of the resulting sliver. If the sliver is taken off the opposite side of the belt 71 (with the angle of roll 76 changed appropriately) the fibers marked B will be on the inside of the resulting sliver.

In one construction, the fibers marked B are cotton staple fibers, While the fibers marked A are 1 /2 d.p.f. drawn polyethylene terephthalate fibers of 1 /2 inch length to form a non-pilling high strength yarn having a strong polyester core and a non-pilling cotton surface which can accept the usual cotton dyes. The bands 72, 73 here may also be of such width as to supply equal weights of the two staple fibers.

It is to be understood that the foregoing detailed description is given merely by way of illustration and that variations may be made therein without departing from the spirit of our invention. The Abstract given above is for the convenience of technical searchers and is not to be used for interpreting the scope of the invention or claims.

-What is claimed is:

1. In the process for making a drawn tow band by drawing sub-tows of continuous filaments in side-by-side contact in a drawing zone to produce a tow band having its subtows cohered together by filament intermingling at their edges, the improvement which comprises supplying to said drawing zone sub-tows of different filaments in a predetermined arrangement of said sub-tows whereby to produce a drawn tow band having a predetermined non-uniform distribution of different filaments across its Width, mechanically crimping the drawn tow band, deregistering the crimps in adjacent filaments, spreading the crimped deregistered tow band to produce a cohesive web having a predetermined non-uniform distribution of said different filaments across its width, said distribution being substantially uniform longitudinally of said web, crosslapping said web to produce a batting whose cross-section has a predetermined non-uniform distribution of said filaments, needling said batting and impregnating said batting to deposit a microporous rubbery material therein and coating the impregnated batting With an abrasionresistant surface layer to form an artificial leather.

References Cited UNITED STATES PATENTS 3,248,103 4/1966 Tarbell 28-1 CF 1,611,462 12/1926 Lambert 19163 3,523,059 4/1970 Coates 156-148 10 3,067,483 12/1962 Hollowell 117140 A 3,208,875 9/1965 Holden 117140 A DANIEL J. FRITSCH, Primary Examiner US. Cl. X.R.

Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3952121 *Aug 8, 1973Apr 20, 1976Rontex America, Inc.Felted web and method of making the same
US4043855 *Mar 3, 1975Aug 23, 1977Compagnie Des Etablissements Dela RisleMulti-layer article and a process and an apparatus for its manufacture
US4129675 *Dec 14, 1977Dec 12, 1978E. I. Du Pont De Nemours And CompanyProduct comprising blend of hollow polyester fiber and crimped polyester binder fiber
US4234374 *Oct 10, 1978Nov 18, 1980The Boeing CompanyBi-directional step-over tape applicator head
US5057168 *Aug 23, 1989Oct 15, 1991Muncrief Paul MMethod of making low density insulation composition
US6736915 *Apr 18, 2002May 18, 2004Lear CorporationMethod of forming a headliner
US20020112806 *Apr 18, 2002Aug 22, 2002Lear CorporationMethod of forming a headliner
EP1950184A2 *Sep 28, 2000Jul 30, 2008Rockwool International A/SBonded fibre products
WO1982001683A1 *Nov 17, 1980May 27, 1982Co BoeingBi-directional step-over tape applicator head
WO2001023312A1 *Sep 28, 2000Apr 5, 2001Grove Rasmussen SvendBonded fibre products
WO2002026649A1 *Aug 2, 2001Apr 4, 2002Jacobsen BentBonded fibre products
Classifications
U.S. Classification156/148, 156/204, 19/150, 156/183, 156/280, 156/181, 19/163, 428/315.5, 428/107, 428/156, 428/126, 156/166, 428/904
International ClassificationD04H1/74
Cooperative ClassificationD04H1/74, Y10S428/904
European ClassificationD04H1/74