US3093163A - Patterned rough-textured pile fabric floor covering - Google Patents

Description

June 1963 R. J. JACKSON ETAL 3,093, 3

PATTERNED ROUGH-TEXTURED PILE FABRIC FLOOR COVERING Original Filed March 16, 1959 6 Sheets-Sheet 1 M6 0 00 1/ ay X s I; w I 2 m. a M 7 40 .14 4

( l0 T J {J June 11, 1963 R. J. JACKSON ETAL 3, 3

PATTERNED ROUGH-TEXTURED PILE FABRIC FLOOR COVERING Original Filed March 16, 1959 6 Sheets-Sheet 2 M #5 M6 4 lid June 11, 1963 R. J. JACKSON ETAL 3,

PATTERNED ROUGH-TEXTURED PILE FABRIC FLOOR COVERING 6 Sheets-Sheet 3 Original Filed March 16, 1959 June 11, 1963 R. J. JACKSON ETAL 3,093,163

PATTERNED ROUGH-TEXTURED PILE FABRIC FLOOR COVERING 6 Sheets-Sheet 4 Original Filed March 16, 1959 June 11, 1963 R. .1. JACKSON ETAL 3,

PATTERNED ROUGH-TEXTURED FILE FABRIC FLQOR COVERING 6 Sheets-Sheet 5 Original Filed March 16, 1959 June 11, 1963 R. J. JACKSON ETAL 3, 9

PATTERNED ROUGH-TEXTURED PILE FABRIC FLOOR COVERING 6 Sheets-Sheet 6 Original Filed March 16, 1959 3,093,163 PATTERNED ROUGH-TEXTURED PILE FABRIC FLOOR COVERING Robert J. Jackson, Hazardville, and Raymond J. (Iarrigan, Thompsonville, Conn, assignors to Bigelow-Sanford, Inc., a corporation of Delaware Original application Mar. 16, 1959, Ser. No. 799,541, now Patent No. 3,009,485, dated Nov. 11, 1961. Divided and this application Get. 20, 1959, Ser. No. 847,605

2 Claims. (Cl. 139-396) The present invention relates to pile fabric floor covering and more particularly to a rough-textured, patterned woven pile fabric floor covering.

An object of the invention is to provide a roughtextured loop-pile fabric floor covering woven on a modified carpet loom without the use of the conventional pile wires and provided with a pattern produced by differences in the lengths, or heights, of the loops.

A further object of the invention is to provide a looppile carpet wherein the heights of the pile loops vary haphazardly, or at random, within controllable limits, to give an overall rough surface texture and wherein a pattern due to further variation of pile height between different areas of the carpet is present.

A further object of the invention is to provide a loop pile fabric floor covering having a novel and attractive over-all rough-textured pile surface formed by pile loops of irregular random heights within a controllable range of heights and having a surface pattern, of difierent height loops or different color loops, or both, superposed on the random loop heights.

This application is a divisional application filed as a result of a requirement for restriction under 35 U.S.C. 121 in our copending parent application Serial No. 799,541, filed March 16, 1959, Patented November 21, 1961, No. 3,009,485, in which parent patent our method and apparatus for making the product of the present application are claimed. The inventions of the present application and of said parent application are in the nature of improvements on the invention of our copending a plication, Serial No. 852,546 filed November 12, 1959 as a continuation-in-part of our prior application Serial No. 823,757 filed June 29, 1957, which in turn was a continuation-in-part of our prior application Serial No. 749,205, filed July 17, 1958, all now abandoned. According to the invention claimed herein, the carpet is provided with a pattern due to differences in loop heights. In the carpet of said application Serial No. 852,546 (and Serial Nos. 749,205 and 823,757) the height of the pile loops varies from loop to loop in a wholly random or haphazard manner, within a small controllable range of heights. This same random height variation is present in the carpet of the present invention and, in addition, the height of the loops is further varied, in accordance with a pattern, from place to place in the carpet surface to provide a pattern due to difference in loop height, the carpet having a rough-textured pile surface due to the random height variation. Further, in accordance with the present invention, the patterned height variation may be so arranged as to produce a pattern due to differences in the appearance of the pile at different places in the pile surface, e.g., differences in color.

The pile floor covering of the invention comprises a backing formed from wefts, binder warp yarns and stuffer warp yarns, which may be a backing construction such as is used in the well known velvet or Wilton carpet woven on a pile wire loom, or an Axminster type backing, the wefts lying in two planes, above and below the stuffer warp yarns, and being bound against the stuffer warp yarns by binder warp yarns passing about the wefts. The

rates atom ice pile surface is formed by pile warp yarns which rise above the upper wefts as pile loops, which, if desired, can be sheared to form pile tufts, and which are of different heights in accordance with a pattern. The haphazard or random pile height variation extends throughout the pile face, the difference in height due to this variation being slight but sufficient to be clearly apparent, say a difference of the order of /8 inch, or more or less, with loops of random intermediate heights between the highest and lowest, and with an entirely random or haphazard distribution of such heights among all the pile loops forming the pile face, providing a novel and attractive rough-textured and patterned pile surface.

We make this novel pile fabric by forming a first shed of the warp yarns, including the stuifer warp yarns, the pile warp yarns and the binder warp yarns, inserting a first weft in the shed and beating-up this weft less than the full distance to the weaving points or fell of the fabric so that this weft through its extent between the selvages is left between the warp yarns at an appreciable and substantially uniform distance from the fell of the fabric. While the first weft is so spaced from the fell, a second shed is formed in which the positions of binder warp yarns which in the first shed were in a different plane from the stulfer warp yarns are reversed to the other plane of the shed. The stuifer warp yarns and pile Warp yarns also are reversed so that at least certain pile warp yarns are in different shedlines or planes in the first and second sheds and therefore extend between the wefts inserted in these sheds. A second weft is inserted into this second shed. The second weft is then beaten up completely to the fell of the fabric and the first weft is carried ahead of it, also to the fell of the fabric. Due to the change of binder warp yarns and pile warp yarns between the first and second sheds, pile warp yarns lie between the two wefts and as the second weft approaches the first weft, in its beat-up travel, the two wefts are constrained toward each other by binder warp yarns, causing pile warp yarns to be pinched between the two wefts so that these pile yarns are pushed forward by the wefts in their beat up travel, causing the portions of such pile warp yarns between the fell and the wefts to buckle upwardly to form a row of pile loops. The loops so produced differ at random in height.

In accordance with the method aspect of the invention, (not claimed herein), we selectively vary the tension in the pile warp yarns supplied to the sheds, in accordance with a pattern. At any particular beat of the lay, different pile warp yarns may be under different tensions and each pile warp yarn may be under different tensions at different beats. We have found that such variation of tension will vary the height of the loops formed by the procedure just described to produced a pattern of higher and lower loop heights susperposed on the random loop heights. The loops so formed in pile warp yarns which are under greater tension are lower than the loops formed at the same time in the pile warp yarns which are under lesser tension.

The method may be carried out on a carpet loom generally similar to the conventional carpet looms but modified so that the lay in its forward motion on alternate beats is checked at a predetermined point short of the fell of the fabric to give only a partial beat up; but is not so checked in its forward motion on the intermediate beats, and modified in accordance with the apparatus aspect of the invention by the addition of means for selectively varying the tension in the individual pile warp yarns in accordance with a pattern. Mechanism is provided for assuring disposition of the partially beaten up wefts at a uniform, or substantially uniform, distance from the fell along their entire length between the selvages. The customary pile wires and the pile wire motion are not required and may, if present, be omitted from the loom.

Other objects, features and advantages of the invention will become apparent from the following detailed description of one particular, presently preferred, embodiment of the same, in which reference is made to the accompanying drawings wherein:

FIG. 1 is a vertical longitudinal sectional view of a carpet loom on which the fabric of the invention may be woven, showing the lay in full lines in its rearward position and in dot-dash lines in its fully forward position;

FIG. 2 is similar to FIG. 1 but shows the lay in its forward position at the end of a partial beat up;

FIG. 3 is a horizontal sectional View taken on line 3-3 of FIG. 1;

FIG. 4 is a detail vertical longitudinal sectional view taken on line 44 of FIG. 3;

FIG. 5 is a schematic view in plan illustrating the manner of operation of a weft-positioning device;

FIG. 6 is a fragmentary vertical sectional view, corresponding to a part of FIG. 1 but showing a modification of the lay operating mechanism;

FIG. 7 is a view similar to FIG. 6 but showing the parts in a different position;

FIG. 8 is a horizontal sectional view taken on the line 8--8 of FIG. 6;

FIG. 9 is a vertical sectional view taken on line 9--9 of FIG. 8;

FIG. 10 is a detail sectional view to an enlarged scale taken on line 10-10 of FIG. 1;

FIG. 11 is a detail sectional view taken on line 1 1-1 1 of FIG. 10;

FIG. 12 is a view similar to FIG. 11 but showing an alternative way of threading in the pile warp yarns;

FIGS. 13 through 18 are diagrammatic warpwise sectional views through the fabric, shed and reed illustrating successive positions of the warp yarns, wefts and reed during one cycle of the weaving operation;

FIG. 19 is a perspective view of the fabric of the invention, after weaving;

FIG. 20 is a vertical warpwise sectional view on line 2020 of FIG. 19;

FIG. 21 is a vertical warpwise sectional view on lines 21-21 of FIG. 19;

FIG. 22 is a photographic plan view of the pile face of a fabric of the invention;

FIG. 23 is a warpwise sectional view of a modified weave; and

FIG. 24 shows a modified tension control means.

In order that the description and disclosure hereinafter of our novel fabric claimed herein may be better understood, we will first describe our method and apparatus for the manufacture thereof. Referring to the drawings, we have shown so much only of a conventional velvet carpet loom as is necessary to show the relationship of the structural features of the loom of our invention thereto. The loom comprises side frames 2 and 4 interconnected by cross girts 6 (one only is shown) to provide the main frame on which the various loom operating parts are supported. At the forward end of the loom a breast beam 8 extends between the side frames 2 and 4, supporting the woven fabric as it is advanced thereover from the weaving point or fell by the conventional take-up roll (not shown). A lay 10 is supported on the conventional lay swords 12, 13, each sword being pivoted on the loom frame, as at 14, for oscillatory movement back and forth about a common axis. The reed 16 is carried on the lay between the reed cap 18 and the lay bed, being clamped to the latter by the reed clamp 20 which affords a raceway for the shuttle which inserts the wefts into the warp sheds.

It will be understood that although a shuttle is employed in the particular loorn described, the wefts may be inserted by the use of a needle, as is well known in the carpet weaving art, and although the particular loom shown and described is a velvet carpet loom the loom may instead be any pile wire type of carpet loom, such as a jacquard carpet loom (without employing the jacquard apparatus), or an Axminister type loom, with modifications which will be obvious to those skilled in the art in view of the disclosure herein.

Oscillatory movement of the lay forwardly to beat up a weft and rearwardly to permit insertion of the next weft is effected by means of the crankshaft 22 extending between the side frames 2, 4 and having a crank 24 connected to the lay sword 12 by a pitman 25 and a crank 26 connected to the lay sword 13 by a pitman 28. The parts thus far described are conventional.

The wristpins 30, 32 with which the pitmans engage, are adjustable on the lay swords for movement closer to or farther away from the crank shaft 22 to, in effect, change the effective throw of the cranks 24, 26 and thus alter the length of the travel of the lay so that the lay makes only a partial beat-up on alternate forward movements and makes a full beat-up on .the intermediate forward movements. One suitable mechanism for accomplishing this motion of the lay is shown in FIGS. 1, 2 and 3 and another suitable mechanism for this purpose is shown in FIGS. 6, 7, 8 and 9 but it will be understood that various other means may be employed for this purpose in combination with conventional loom parts.

Referring to FIGS. 1, 2 and 3, the 'wristpin 30 is mount ed eccentrically on an eccentric disk 34 which is fast to and supported by a shaft 36 passing through and journaled in the lay sword 12. Fast on the other end of shaft 36 is a pinion 38. The pinion 38 is adapted to be oscillated about its axis through an angle of about 180 to change the position of the wristpin 30 with respect to the lay, and thus the effective throw of the crank 24, by means of a spur gear 40 fast on the outer end of a shaft 42 which extends between and is journaled in the lay swords. Similar mechanism is provided at the other side of the loom for oscillating the wristpin 32, comprising eccentric disk 44, shaft 46, pinion 48 and the spur gear 50 fast on shaft 42.

The shaft 42 (and spur gears 40, 50) is rocked in timed relation with the beats of the lay by mechanism now to be described. On the picker shaft 52, a conventional shaft in tapestry and velvet carpet looms, is fixed for rotation with the shaft a face cam 54 having a cam track 56. The cam track 56 guides a cam follower roller 58 extending sidewise from a lever 60 pivoted at 62 on the stationary bracket 64 carried on a cross girt 6. The opposite end 66 of lever 60 is connected through a pull rod 68 to a crank 70 fixed on shaft 42 but rotatably adjustable thereon, as by loosening and resetting of the set screw 72 (FIG. 3). The pull rod 68 is adjustable in length, as by means of a turnbuckle 74.

The picker shaft 52 rotates at half the speed of the crank shaft 22. The cam 54 is so shaped that it pro duces the described alternate full and partial forward beats of the lay. The cam is also so shaped as to cause the effective throw of the cranks 24, 26 to be shortened during a forward motion of the lay and lengthened during a return motion of the lay, so that the component of motion imparted to the lay by change of position of the wrist-pins 30, 32 is subtractive from, rather than additive to, the motion imparted to the lay by the cranks 24, 26, and the motion of the lay thus eased. For these purposes, the cam track 56 includes a semi-circular lobe 76, a rise 78 and a fall 80, the latter two portions of the cam track each extending through of cam rotation.

In FIG. 1 the lay (full lines) is in its backward position, the wrist pins 30, 32 are in their position nearest the crank shaft 22 and the cam follower 58 lies at the junction of the semi-circular lobe 76 and the rise 78. As the crank shaft 22 rotates counter-clockwise through to the position of FIG. 2, the cam 54 rotates counter-clockwise through 90" to the position of FIG. 2, and the cam follower 58 passes over the rise 78 to depress lever 60 and oscillate the wristpins 30, '32 into the position shown in FIG. 2, i.e., their position most remote from the crank shaft 22. During this interval the lay is moved forwardly from its backward position, but, due to the motion of the wrist pins during this interval, the lay is arrested short of its fully-forward position and the reed beats the weft only part way to the fell of the fabric, to the position shown in FIG. 2.

During the second 180 of counter-clockwise rotation of the crank shaft 22 the lay is returned to its backward position and cam 54 is rotated counter-clockwise 90, moving the cam follower 58 over the fall 80 of the cam and lifting the lever 60. Thus the wrist pins 30, 32 during this stroke will move into their position nearest to the crank shaft 22. As this, in effect, lengthens the throw of the crank 24, 26 the lay motion added by the oscillation of the wrist pins is subtracted from the position imparted to the lay by the cranks 24, 26.

During the third 180 of rotation of the crankshaft 22 the lay and reed again move forwardly. As the wristpins are in their position nearest the crankshaft and as the cam follower 58 is now passing along the circular portion 76 of the cam track and thus does not alter the position of the wristpins, the lay makes a full beat to the position shown in dot dash lines in FIG. 1.

During the fourth 180 of rotation of the crankshaft 22 the lay and reed are moved backwardly and the cam follower 58, again traveling along the circular portion 76 of the cam track, does not alter the position of the wrist pins 30, 32. The parts now have returned to their initial position of FIG. 1 (full lines) to complete a cycle of operation of the reed.

Referring now to the modification of FIGS. 6, 7, 8 and 9, the described motions of the lay in this modification also are produced through the crank shaft 22 and pitmans 25, 28 under the control of the cam 54, cam follower 58 and pull rod 68. The pull rod 68 is pivotally connected at 82 to a rack 84 which is slidable endwise of the lay sword 12 in fixed guides 86, 88 thereon. The cam 54 is so located on shaft 52 that the pull rod 68 is aligned with the rack 84. The rack '84 meshes with a pinion 90 fixed to a shaft 92 journaled for rotation in the lay sword 12. Fixed to the shaft 92 are two circular eccentric disks 94, 96 lying adjacent the side surfaces of the lay sword and respectively engaging, through ball bearings 95, 97, the plates 98, 100 which are movable in supports 102 on the lay sword. Plates 98, 100 are interconnected by wristpin 104 which passes through horizontally elongated openings 106, 108 in the sword. The wristpin 104 is the wristpin for the pitman 25.

Endwise movement of the rack 84 by pull rod 68 under the influence of the cam 54 causes oscillation of the pinion 90 through approximately 180 and with it of the eccentric disks 94, 96, thus moving the plates 98, 100 and with them the wristpin 104 to change the effective throw of crank 24, as in the case of the corresponding movement of wristpins 30, 32 in the modification of FIGS. 1, 2 and 3. A similar arrangement of cam 54, pull rod 68, rack, pinion, eccentric disks, and plates is provided on the other lay sword, 13, similarly cooperating with the pitman 28 and crank 26.

The pile warp 110 (FIG. 1) is supplied from a beam 112 supported on the side frames 2 and 4 at the top of the loom as appears in FIG. 1. From the beam 112 the pile warp passes forwardly to the weaving point over a whip roll and through the heddle eyes of the harnesses which may in general arrangement be conventional, for example as shown in Patent. No. 1,840,855. Thus the pile warp 110 passes forwardly from the beam 112 over and forwardly of the shaft 114 (FIG. 11) and downwardly to whip roll 116. The pile yarns pass rearwardly of and below the whip roll 116 and thence forwardly through the pile heddle frame 117 and the reed 16 to the fell of the fabric. The whip roll 116 is mounted'for rotation on the rocking arms 118, one at each side of the loom, which are mounted for swinging movement about the axis of shaft 114 carried on the loom frame, and are urged by springs 120, and arms 122 rigid with arms 118, to swing counterclockwise as seen in FIG. 11 to tend to move the whip roll 116 away from the weaving point. Thus the pile yarns are maintained under the desired tension determined by the springs The whip roll arrangement so far described is conventional.

We provide means for selectively varying the tension in the pile yarns in accordance with a pattern. In the embodiment shown, a shaft-124 is mounted to extend between the arms 118 for rotation in bearings provided on the arms. The shaft 124 carries a series of rollers 126, 128, 130, 132 and 133 each having an eccentric bore through which the shaft 124 passes. Each roller is secured to the shaft 124 for rotation therewith by a set screw 134 set in a recess below the peripheral sur face of the roller. The pile yarns pass over the peripheries of the rollers 126-133 and each roller may be provided with small flanges as at 136 to keep the yarns from slipping sidewise off the roller.

Shaft 124 is driven in timed relation with the weaving motions of the loom. The shaft may be driven by an independent drive, through a change-speed gear, but we prefer to take the drive from a moving part of the loom. In the embodiment shown, shaft 124 is provided with a sprocket 138 (FIG. 10) fixed thereon and driven by a chain 140 trained about a sprocket 142 fixed on a hub 144 to which also is fixed a sprocket 146. The sprocket 146 is driven by a chain 148 which passes upwardly and about a sprocket 150 (FIG. 1). The sprocket 150 is driven through a change-speed gear box 152 by the chain 154 which in turn is driven by a sprocket 156 fast on the crank shaft 22. It Will be understood that the drive for the eccentric roller shaft 124 might equally well be taken from the picker shaft 52, or other moving part of the loom, appropriate adjustment in the speed ratio of the driving connections being made.

As the rollers 126-133 rotate they increase and then decrease the tension in the pile warps by deflecting the warps more and then less from a straight line in their passage from shaft 114 to whip roll 116. Thus the pile yarn 158 is under maximum tension as the high point of roller 126 engages it in the position shown in FIG. 12.

Some of the pile yarns may be passed over one side and other pile yarns over the other side of the rollers to produce various pattern variations. Thus, in FIG. 12 alternate pile yarns, as 158, are passed over the rear ward faces of the rollers and the intermediate pile yarns 160 are passed over the front faces of the rollers, to cause the tension in the alternate yarns to be at a maximum when the tension in the intermediate yarns is at a minimum. The alternate yarns 158 may difier from the intermediate yarns 160 in appearance or other characteristic, for example, in color.

In the method of our invention the formation of the pile is dependent upon disposition of certain wefts at an appreciable distance from the fell following the beat up of these wefts. Customarily, the loom is timed so that the wefts are inserted when the reed is in or near its rearward position and thus the shuttle travels through the shed at some distance from the fell. The weft being inserted is bound in the selvage tightly against the fell on the side of the fabric at which the shuttle (or needle) enters and, accordingly, until it is fully beaten up, the weft does not extend straight across the fabric but lies at an inclination to the warp yarns, being at the fell at one selvage and spaced from the fell at the other selvage. Such oblique disposition of a weft which is to be partially beaten up would cause the pile loops formed nearer the weft end nearest the fell to be lower than loops formed farther from this end of the weft, introducing an objectionable dissymmetry of pile height weft-wise of the fabric. We overcome this diflieulty by making provision for positioning of such wefts so that following the partial beat up the weft will extend across the fabric at the same distance from the fell throughout its length. Referring particularly to FIGS. 3, 4 and 5, at the left end of the breast beam 8 a plunger 162 is mounted for sliding movement in a housing 164 disposed slightly outwardly of the left selvage of the fabric. The plunger 162 is provided on its outer end with a head 166' having a flat face for engagement with an abutment 168 carried on the lay 10. The plunger 162 is urged outwardly of the housing 164, toward the lay, by a compression spring 170 and such outward movement of the plunger is limited by a stop pin 172 threaded into the plunger and extending upwardly through and guided in a slot 174 in the housing 164. The housing 164 and plunger 162 are bodily adjustable on the breast beam toward and from the lay by means of the slots 176 (FIG. 3), through which pass bolts or machine screws 178 securing the housing to the breast beam 8. The travel of the plunger in the housing is adjustable by selectively inserting the stop pin 172 into any one of a series of threaded holes 180.

The operation of this weft positioning device is as follows: Referring to FIG. 5, in the loom and method illustrated, the lower weft shot is picked from the right hand side of the loom (lower side of FIG. the shuttle 182 being received in the shuttle box on the left side, as shown in full lines, after it has laid the lower weft 184. The beat up of the lower weft is a full beat-up so that the weft is carried to the fell of the fabric. As the lay moves forward for this full beat-up of the lower weft 184 of FIG. 5, the abutment 168 on the lay engages the portion 186 of the weft which extends from the selvage 188 to the shuttle and clamps it against the face of the head 166. Continued forward motion of the lay to carry the weft to the fell is permitted by forward motion of the plunger 162 against the action of spring 170. As the lay begins its backward movement, the spring 170 forces the plunger rearwardly to follow the lay so that the head 166 is maintained against the abutment 168 to continue to clamp the weft. The portion 186 of the weft, accordingly, is carried backward by the head 166 until the pin 172 reaches the end of its travel in the slot 174, whereupon the head 166 moves to rest and the abutment 168 moves on, out of contact with the head and weft, leaving the weft portion 186 spaced rearwardly from the fell as shown in full lines in FIG. 5. The pin 172 is so positioned on the plunger 162 that the extreme rearward position of the head 166, when it is at rest, is at least slightly rearwardly of (farther from the fell than) the partially beat up position of the upper wefts. When the shuttle is next thrown, from left to right to its dotted position in FIG. 5, to lay the upper weft 190, the left hand end of the upper weft at the selvage will not be in the fell as is conventional, but will be spaced rearwardly of the fell a distance at least as great as the spacing desired between the fell and this upper weft after it has been beaten-up to its initial beat-up position spaced appreciably from the fell. Accordingly, when the lay next beats forwardly in its partial beat-up of this upper weft 190 and returns to its rearward position it leaves the whole length of the weft, from selvage to selvage, spaced at a substantially uniform distance from the fell.

In weaving on the loom described the fabric of the particular preferred embodiment of the invention herein disclosed, we employ wefts, binder warp yarns, stulfer warp yarns, and pile warp yarns, the binder warp yarns being desirably divided into two series, each series controlled by a separate heddle. The stuifer warp yarns are shedded by a stuffer heddle and the pile yarns are controlled by a separate heddle. 'Ihe stuffer and binder warp yarns are supplied from beams or a creel and are maintained under the conventional tensions long employed in velvet and tapestry weaving, the stuffer warp yarns being under somewhat more tension than the other warp yarns, as is well understood in the art. In FIG. 13 a first warp shed has been formed having in its upper plane the binder warp yarns 192 of the first series and in its lower plane the binder warp yarns 194 of the second series, the stuifer warp yarns 196 and the pile warp yarns 110. A first weft 198 is picked into this shed, which weft, as it is above the stuffer warp yarns, will become an upper weft. The first weft 198 is beaten up as illustrated in FIG. 13, in which the reed 16 is shown at the end of its forward motion, in the relative position shown in FIG. 2, that is, in its forward position on a partial beat-up having been arrested short of the fell 200 of the fabric, so that the first weft 198 is left after beat-up in a position an appreciable distance from the fell.

The first shed is then closed and the second shed, FIG. 14, is formed, containing in its lower plane the binder warp yarns 192 of the first series and in its upper plane, the pile warp yarns 110, the stutfer warp yarns 196 and the binder warp yarns 194 of the second series. All of the warp yarns have been reversed from the positions they occupied in the first shed. A second weft 202 is inserted in the second shed. This weft, being below the stuffer warp yarns 196, will become a lower weft. The reed 16 now beats forward in a full beat, carrying the weft 202 forward to the position shown in FIG. 15. Just before reaching the position of FIG. 15, the reed also engages the first weft 198. Due to the reversal of the binder warp yarns 192 of the first series, between the first shed (FIG. 13) and the second shed ('FIG. 14) the Wefts 198, 202 are constrained toward each other on their forward motion so that they pinch the pile warp yarns between them and on continued forward movement draw the pile warp yarns forwardly, causing pile warp yarns lying between the fell and the partially beatenup position of weft 198 in FIGS. 13 and 14 to buckle upwardly at 204 (FIG. 15) to form a row 206 of pile loops, FIG. 16. The stufier warp yarns, also, are engaged between the wefts 198, 202 but as they are under greater. tension than are the pile warp yarns they are not drawn forward. The pile warp yarns, even when under substantially equal tensions, are not all drawn forward exactly equally, as we have found in practice, with the result that the loops in a weftwise row such as row 206 diifer among themselves in height. Such difference in height between the lowest loop and the highest loops, may be of the order of A2, or more or less, and there are so produced, in each weftwise row, loops of various intermediate heights between the extremes. This height distribution is entirely at random and haphazard within each weftwise row and from row to row, and gives a rough-textured appearance to the pile surface of the fabric. In addition, the loops formed in yarns which are under appreciably greater tension, such as the yarns 158 passing over the high point of roller 126 (FIG. 12), are formed to a lesser length, or height, so that the variation in the tension in the pile warp yarns produced by rotation of the rollers 126, 128, 130, 132 and 133 results in the production of long and short loops in the fabric in accordance with a pattern.

A third shed is then formed, as in FIG. 17, containing in its upper plane the binder warp yarns 194 of the second series and in its lower plane the binder warp yarns 192 of the first series, the stuffer warp yarns 196 and the pile warp yarns 110. This shed is the same as the first shed, FIG. 13, except that the binder warp yarns of the two series are reversed, the yarns 192 of the first series being up in the shed of FIG. 13 and down in the shed of FIG. 17. A third weft 208 (FIG. 17) is inserted in the third shed and beat forward as in FIG. 13 to a distance appreciably short of the fell.

A fourth shed is then formed, FIG. 18, containing in its lower plane the binder warp yarns 194 of the second series and in its upper plane the pile warp yarns 110, the stulfer warp yarns 196, and the binder warp yarns 192 of the first series. This shed is identical with the second shed, FIG. 14, except that the binder warp yarns of the two series are reversed, that is, the binder warp yarns 192 of the first series which were down in the second shed are up in the fourth shed and the binder Warp yarns 194 of the second series which were up in the second shed are down in the fourth shed. A lower weft 210 is picked into the fourth shed. As the reed 16 beats forward on its fourth heat, which is a full beat, the lower weft 210 and the upper weft 208 are forced toward each other to pinch and carry forward with them the pile warp yarns which lie between them, in the same manner as occurred on the second beat-up, as in FIGS. 14, and 16, and producing two kinds of inequalities in the height of the loops so produced, as described in connection with the second beat-up.

The foregoing shedding, weft inserting and beating-up operations form a complete weaving cycle, with four rotations of the crankshaft 22 and two rotations of cam 54. It will be observed that in this specific embodiment the position of the stuffer and of the pile warp yarns in the shed is changed following each beat-up but the binder warp yarns are changed only following alternate beat-ups, i.e., following the insertion and beating-up of the upper weft shots.

The result of this method of weaving is a patterned and rough-textured pile fabric floor covering of the construction illustrated at the left hand side of FIG. 13, the yarns in that figure being shown more widely separated than in the actual fabric for purposes of illustration. The fabric comprises the stuffer warp yarns 196, the pile warp yarns 110, the binder warp yarns 192 and 194 and the wefts 184, 190. The wefts are in pairs, whereof each pair comprises the upper weft 190 lying above the stuffer warp yarns 196 and the lower weft 184 lying below the stuft'er warp yarns and approximately immediately below the upper weft with which it is paired. The binder warp yarns are in two series 192 and 194, the binder warp yarns 192 of the first series passing above the upper weft 190 of alternate pairs 216 of wefts and thence directly between the two wefts of the pair and thence beneath the lower weft 184 of the pair. The binder warp yarns of this series pass between the upper and lower wefts of the intermediate pairs 218 of wefts. correspondingly, the binder warp yarns 194 of the second series pass, as shown, between the upper and lower wefts of the alternate pairs 216, above the upper wefts 190 of the intermediate pairs 218, between the wefts of the intermediate pairs and below the lower weft 184 of the intermediate pairs. The pile warps 110 in this embodiment are woven under all of the upper wefts 190 and extend upwardly between adjacent upper wefts to form rows of pile loops which differ among themselves in height in accordance with the pattern produced by the variation of pile warp tension, with a further over-all random height variation superposed on the patterned height variation.

The pile surface of the pile fabric produced by the particular arrangement of FIG. 12 is shown in FIGS. 19, 20, 21 and 22. The alternate pile yarns 158 and the intermediate pile yarns 160 are of different appearance, in this instance of contrasting colors, and are theaded over opposite sides of the rollers 126-133. All the pile yarns contain warpwise rows of loops, as in FIGS. and 21, which gradually change in height from low to high and back to low. The highest loops 220 in alternate yarns 158 and the lowest loops 222 in the intermediate yarns are disposed along the same weftwise lines 224; the lowest loops in the alternate yarns similarly lying in the same weftwise rows with the highest loops in the intermediate yarns. The higher loops spread out weftwise to cover and obscure the adjoining lower loops in the neighboring rows. The yarns which are controlled by the same roller form strips or stripes 226 in which blocks or areas 228 of higher loops of one color pile yarn alternate with blocks or areas 230 of higher loops of the other color yarn so that a color pattern as well as a pattern of higher and lower loops is provided. In addition, the lowest loop height produced by the rollers 126433 (and the highest loop height as well) differs slightly from loop to loop and from yarn to yarn in a wholly random fashion so that there is a random slight variation in loop height distributed over the entire pile face, and superposed on the patterned and controlled height variation produced by the rollers, resulting in a rough-textured pile surface.

The height of the highest pile loop is determined by the spacing between the fell of the fabric and the position of the reed when it is in its forwardmost position on a partial beat-up. The highest pile loops will be of a height approximately one-half this distance of the reed from the fell, which distance we refer to herein as an appreciable distance, meaning a distance suflicient to produce a useful pile height.

The general level of height of the pile is controllable by varying this partial beat-up distance. This variation may be made by adjusting the length of the pull rod 68 by means of the turnbuckle 74 to change the amount by which movement of the wristpins from their forwardmost to their rearwardmost position changes the effective throw of the cranks 24, 26. The same result may be accomplished by changing the position of the crank 74) on the shaft 42 by loosening the set screw 72, rotating the crank on the shaft as desired, and resetting the set screw. The pile height also may be adjusted by replacing the eccentric disks 34, 44 with disks having wristpins set at different eccentricities, and we prefer this method of adjustment.

Many variations from the particular method, fabric and apparatus described may 'be made within the scope of the invention. For example, the construction of the fabric backing may be diificult from that shown. Thus, the pile yarns may be woven through to the back of the fabric, passing beneath the lower wefts which then serve as the holding wefts, as illustrated in FIG. 23. In this figure, the pile warp yarns appear at 110, the stufier warp yarns at 232 and the binder warp yarns at 234. The pile yarns are raised over each upper weft 236, to form the pile loops 238, and pass beneath each of the lower wefts 240. In Weaving this fabric, all of the pile warp yarns 110, together with all of the binder warp yarns 234, are in the upper line of the shed and the stuffer warp yarns 232 are in the lower line of the shed, when an upper weft 236 is picked. The upper weft is given a partial beatup, as in FIG. 13, and the shed is then changed to reverse all of the warp yarns, i.e., to place the pile warp yarns and the binder warp yarns 234 in the lower line of the shed and the stuifer warp yarns 232 in the upper line of the shed, whereupon a lower weft 240 is picked. The lower weft is then beaten-up fully into the fell of the fabric, as in FIGS. 14, 15 and 16, together with the immediately preceding upper weft, the two wefts grasping the pile warp yarns between them to form a pile loop 238.

The rollers may be made much narrower than those illustrated and increased in number, for example to provide a roller for each two pile yarns, or for each pile yarn, to provide the possibility of controlling the pattern in the pile face at each pair of pile yarns or at each pile yarn and at every pick. The rollers may be of other shapes than the circular shape shown.

Other means than that described may be employed to periodically vary the tension in the pile yarns. Referring to FIG. 24, the pile warp 110 may be supplied from packages 241 in a creel 242, each yarn passing from its package over a guide bar 244 and through an opening in a weight 246 pivoted on an arm 248 which in turn is pivoted at 250 on the creel 242. The tensions in the pile yarns may be varied by means of rotary cams 252, one for each arm 248, mounted on a shaft 254. The shaft 254 is driven in timed relation with the weaving motions of the loom, for example from the picker shaft 11 52 through suitable sprockets 256, 258 and 260 and chains 262 and 264. As the cams 252 rotate they raise and lower the weights 246 and thus vary the tension in the pile yarns.

Accordingly, as different embodiments of the invention may be made without departing from the spirit and scope thereof, it is to be understood that the invention is not limited to the specific fabric disclosed except as defined in the appended claims.

We claim:

1. A patterned, rough-textured pile fabric floor covering comprising stutter warp yarns, upper wefts lying above the stuffer warp yarns, lower wefts lying below the stufier warp yarns, binder warp yarns woven above upper wefts and below lower wefts, and pile warp yarns woven below the upper wefts and extending upwardly between adjacent upper wefts to form weftwise rows of pile loops, alternate pile warp yarns differing from the intermediate pile warp yarns in color, the pile loops in each pile yarn varying in length along the length of the pile yarn in accordance with a pattern, the longer loops extending sidewise to hide adjoining lower loops, the loops in alternate rows being long in areas where the loops in intermediate rows are short and short in areas where the loops in intermediate rows are long, whereby the pile surface is provided with a color pattern, the pile loops further having a haphazard sequence of varying heights within a range of inch warpwise and weft wise superposed on said patterned variation in length, giving a correspondingly rough texture appearance to the patterned pile surface.

2. A patterned, rough textured pile fabric floor cover- 111g compnsing stutter warp yarns,

upper wefts lying above the stutfer warp yarns,

lower wefts lying below the stutter warp yarns,

binder warp yarns woven above upper wefts and below lower wefts, and

pile warp yarns woven below the upper wefts and extending upwardly above the upper wefts to form weftwise rows of pile loops,

all of the pile loops in at least certain warpwise rows varying regularly in height along the row in accordance with a pattern, and

the pile loops in all of at least certain adjacent weftwise rows differing in height along the weftwise rows regularly in accordance with a pattern, and

all of the pile loops in said pile fabric further having a haphazard warpwise and weftwise sequence of varying heights within a range of superposed on said patterned height variations, giving a correspondingly rough textured appearance to the patterned pile surface.

References Cited in the file of this patent UNITED STATES PATENTS 541,645 Weaver June 25, 1895 1,766,805 Wakefield June 24, 1930 2,164,090 Shuttleworth June 27, 1939 2,650,621 Crawford Sept. 1, 1953 2,695,634 Miller et a1. Nov. 30, 1954 2,702,056 Hoeselbarth Feb. 15, 1955 2,715,921 Smiley Aug. 23, 1955 2,750,969 Hoeselbarth June 19, 1956 2,988,113 Smiley June 13, 1961 2,997,074 Law Aug. 22, 1961 FOREIGN PATENTS 63,617 Netherlands July 15, 1949

Claims (1)

1. A PATTERNED, ROUGH-TEXTURED PILE FABRIC FLOOR COVERING COMPRISING STUFFER WARP YARNS, UPPER WEFTS LYING ABOVE THE STUFFER WARP YARNS, LOWER WEFTS LYING BELOW THE STUFFER WARP YARNS, BINDER WARP YARNS WOVEN ABOVE UPPER WEFTS AND BELOW LOWER WEFTS, AND PILE WARP YARNS WOVEN BELOW THE UPPER WEFTS AND EXTENDING UPWARDLY BETWEEN ADJACENT UPPER WEFTS TO FORM WEFTWISE ROWS OF PILE LOOPS, ALTERNATE PILE WARP YARNS DIFFERING FROM THE INTERMEDIATE PILE WARP YARNS IN COLOR, THE PILE LOOPS IN EACH PILE YARN VARYING IN LENGTH ALONG THE LENGTH OF THE PILE YARN IN ACCORDANCE WITH A PATTERN, THE LONGER LOOPS EXTENDING SIDEWISE TO HIDE ADJOINING LOWER LOOPS, THE LOOPS IN ALTERNATE ROWS BEING LONG IN AREAS WHERE THE LOOPS IN INTERMEDIATE ROWS ARE SHORT AND SHORT IN AREAS WHERE THE LOOPS IN INTERMEDIATE ROWS ARE LONG, WHEREBY THE PILE SURFACE IS PROVIDED WITH A COLOR PATTERN, THE PILE LOOPS FURTHER HAVING A HAPHARZARD SEQUENCE OF VARYING HEIGHTS WITHIN A RANGE OF 1/8 INCH WARPWISE AND WEFTWISE SUPERPOSED ON SAID PATTERNED VARIATION IN LENGTH, GIVING A CORRESPONDINGLY ROUGH TEXTURE APPEARANCE TO THE PATTERNED PILE SURFACE.

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