This invention relates to industrial woven textile fabrics, and the provision of seaming areas at opposed ends of such fabrics to be joined in a seam. More particularly, the invention relates to improvements in the provision of seaming loops to warp yarns, where the yarn ends are secured to the fabric body in a bonding process.
Industrial textiles such as those intended for use in the dryer section of a papermaking machine are generally flat woven using a wide industrial loom. In these fabrics, the warp yarns will be oriented in the machine direction (MD) or running direction, while the weft yarns will be interwoven across the warp and thus oriented in the cross-machine direction (CD) or transversely to the warp in the plane of the fabric. Examples of fabrics of this type are described in U.S. Pat. No. 4,209,290 (Buchanan et al.) and U.S. Pat. No. 5,103,874 (Lee) and its continuations and divisions. In these fabrics, the warp yarns will have a generally rectangular or square cross-sectional configuration so as to maximize contact between the fabric and product conveyed thereon. Flat woven fabrics such as these must be seamed prior to use so that the opposed ends can be joined together to render the fabric endless on the machine for which they are intended. Pin seams or streamline coil seams such as are well known in the art are generally used for this purpose, both of which require a pintle or pin to close them.
Prior to the present invention, seams intended for use in woven industrial textiles having two layers or sets of warp yarns, such as those described in U.S. Pat. No. 4,209,290 (Buchanan et al.) and U.S. Pat. No. 5,103,874 (Lee), were generally formed by the MD yarns from one fabric surface being turned around either the last weft yarn in the fabric, or a spacer positioned after the last weft yarn, thus forming respectively retainer loops and seaming loops, the free ends being rewoven back into the fabric, as discussed below.
This method of the prior art is shown in
To accommodate the loops from the opposite fabric end and allow for their interdigitation to form the closed seam (so that the seaming loops from the two fabric ends can be intermeshed together and a pin inserted into a common channel), it is necessary to have open spaces on opposite sides of the fabric along the seam face (i.e. locations at which there are no warp seam loops). This type of arrangement can be seen in
The use of seaming loops of this nature is also well known for single layer fabrics, for example U.S. Pat. No. 5,454,161 (Scarfe), U.S. Pat. No. 5,488,976 (Lorenz) and U.S. Pat. No. 5,713,398 (Josef).
Seam creation in a woven textile is a process which, although partially automated, requires a high degree of training, skill, dexterity and time on the part of an experienced seamer. The cost of forming such seams, particularly the reweaving steps, accounts for a high proportion of the cost of making the fabric. Thus, it would be desirable if a means were available whereby a reliable and high strength seam could be formed in fabrics such as are described above without the need to reweave the warp ends back into the fabric to the extent presently required. Such a means would reduce labour costs associated with seam formation resulting in lower overall manufacturing costs, and should provide a seam of higher strength and reliability than has previously been available.
It has now been found that a seaming area can be provided which is similar in appearance to known seaming areas such as shown in
Techniques and means of welding or bonding yarns to form a high strength seam are known. For example, U.S. Pat. No. 5,377,722 to Jaala discloses a fabric seam suitable for a dryer fabric made by removing some material from the warp on the MS side of the fabric, folding the fabric ends so that they are double, and then stitching the doubled part together and attaching a spiral for seaming. The stitches are so placed that their yarns lie between the warps and are placed below the contact area of the warps so that they will not be exposed to wear. The stitch portion remote from the seam is locked in position by an adhesive, such as silicone, which is applied within the fold area on the wear surface of the fabric.
U.S. Pat. No. 5,464,488 to Servin discloses a method for bonding two woven fabric layers by ultrasonic welding. The layers are overlapped and their yarns softened by the ultrasonic apparatus; the yarns of each layer are then pressed together, causing them to adhere to one another. The method may also be used to attach seaming coils at a foldback, the foldback being welded into position to secure a flap, or repair a hole.
U.S. Pat. No. 5,713,399 to Collette et al. discloses a method of making a papermaker's fabric, and the fabric so obtained, by manufacturing a narrow woven fabric strip, spirally winding the strip so that a first lateral edge abuts a second lateral edge of an adjacent turn, and then ultrasonically seaming the abutting edges together. The fabric strip, which is provided with a fringe approximately 4 mm wide, in which there are no warp yarns, is unwound so that the lateral fringes overlap or underlap an immediately adjacent similarly prepared strip, and the non-fringed bodies of the two fabrics abut one another in a common plane. The fringed portions thus form a lap joint while the fully woven body portions form a butt joint. The overlapped portions of the adjacent strips are compressed between an ultrasonic welding apparatus and anvil and thereby welded. The anvil is a rotating wheel over which the seam is welded in a continuous process.
U.S. Pat. No. 6,440,881 to Ercken discloses a seamed press felt wherein the opposed fabric ends which are to be joined are held together by means of an adhesive; there is no mechanical join such as a pin seam. According to the invention, the fabric ends are cut to form overlapping stepped surfaces about 5-15 cm long. One or both surfaces are provided with an adhesive layer, such as a hot melt adhesive or adhesive fibers. The step surfaces are then overlapped and the joint formed by activating the adhesive; the fabric can either be flat or endlessly woven.
U.S. Pat. No. 7,005,038 to Maguire discloses a seam for a metal wire belt for corrugating or liner board applications which is intended to overcome problems of seam fatigue and failure due to loss of strength and malleability at the brazed area of a welded seam for metal wires.
JP 2000/239940 (Nippon Filcon Co. Ltd.) discloses a seam for an industrial textile in which the seaming loops are formed by welding the tips of adjacent warp yarns in a portion of the fabric made up only of warps which is created by removing weft yarns on both fabric ends.
US 2006/0180273 to Beck discloses a method for splicing or joining a multilayer fabric such as a forming fabric by first separating the layers from each other in the region of the free ends (where the splice is to be located). The ends are joined by first overlapping and then linear fusing the yarns under pressure and at an elevated temperature. A reinforcing strip or a perforated adhesive layer is then located in between the layers; the adhesive is then activated or an adhesive is applied to the reinforcing strip to join it to the bottom layer.
US 2007/0028997 to Best et al. discloses a forming fabric in which, in order to enhance stability, warp and weft yarns are fused to one another at their crossing points by means of laser energy; the fabric includes a first set of yarns which absorb laser energy readily.
US 2008/0230139 to Enqvist et al. discloses a seam for a dryer fabric having at least two superposed MD yarn systems, similar to that described in U.S. Pat. No. 5,148,838. According to the disclosure, alternating PS MD yarns form seaming loops while the remainder form the seam edge; all are fastened off on the MS. According to the disclosure, these “fasten-off” rows do not need to be reinforced with an adhesive because they are separated from each other in the fabric. However, this disclosure does not address the fundamental problem of eliminating at least some of the labour required to weave back the warp yarns into the fabric body from the seam area.
WO 2009/032271 to Eagles discloses the use of laser energy to weld or melt selected locations of a papermaking fabric, but in particular at the seam region so as to increase seam strength and durability, while maintaining fabric properties at the seam region essentially the same as within the fabric body. The publication is directed to a method of treating a yarn by providing a material that absorbs short wavelength infrared energy to a fiber which is normally transparent to this energy, and then selectively melting, fusing or bonding the yarn to itself or another yarn by exposure to the energy.
WO 09032666 to Lafond et al. discloses ultrasonic gap welding of flat woven fabrics and specifically, a method of ultrasonic welding the seam termination yarn ends of a fabric using a controlled gap.
Loop-forming seams intended to accept a pintle or seaming coil are well known from the prior art. For example, GB 1529728 to MacBean discloses a woven fabric including a plurality of pre-crimped replacement MD oriented monofilaments in the seam area intended to improve the flatness and stability of the seam area. JP 2005-096109 to Kitamura et al. discloses a loop forming seam for a sludge dewatering fabric in which alternating long and short loops are formed to accept two pintles and thereby increase seam strength and the service life of the fabric. U.S. Pat. No. 5,238,027 to Lee discloses a stacked warp type dryer fabric including orthogonal seaming loops formed from pre-crimped replacement yarns; a single rectangular stuffer yarn is inserted on each side of the pintle. U.S. Pat. No. 5,188,884 to Smith discloses a low marking dryer fabric pin seam including smaller diameter weft (in comparison to those in the fabric body) near the pintle for a fraction or a full repeat of the weave; this allows small pintle loops to be formed using a length of warp yarn no greater than one warp crimp length. U.S. Pat. No. 5,601,120 to Kuckart et al. discloses a pin seam including double concentric seam loops for a stacked warp type dryer fabric; after heatsetting, a portion of the CD yarns adjacent the seam area are removed and alternate stacked MD yarn pairs are woven back to form a pair of nested orthogonal loops.
None of the prior art specifically addresses a means of forming a reinforced seam for a fabric by turning the MD yarns back upon the fabric body and then bonding the yarns to form high strength loops.
The present invention therefore seeks to provide a seaming area for opposing ends of a flat woven industrial fabric comprised of interwoven polymeric warp and weft yarns, such that two seaming areas can be joined together to create a reinforced seam. The seaming area is suitable for any industrial woven fabric, particularly one having at least two sets of warp yarns, and is particularly suitable for fabric designs which utilize generally rectangular monofilament warp yarns, and in which the warp yarns are oriented in the MD and predominate on one or both of the two planar fabric surfaces, such as are described in U.S. Pat. No. 4,290,209. The seaming area and method of the invention are especially suitable for fabrics having these characteristics and in which the warp yarns are organized in a stacked relationship, such as the fabrics disclosed in U.S. Pat. No. 5,092,373.
In general, in the seams according to this invention, the MD warp yarns are turned back from one surface of the fabric onto the other to form both seaming and retainer loops. A seaming loop is a yarn loop formed at one of the opposed fabric ends and which is intended to accept a seaming element, such as a seaming coil or a pintle or pin, so as to form a join with a similar loop formed at opposite fabric end. A retainer loop is a yarn loop formed at one of the opposed fabric ends which wraps around the last CD or weft yarn in the fabric to hold that weft yarn in place. The free ends of the yarns forming the seaming and retainer loops are then bonded to the surfaces of the warp yarns located either immediately above, below or adjacent to and in proximity of the last weft yarns adjacent a fabric edge, or to selected weft yarns, by means of any suitable bonding process, such as laser energy, ultrasonic energy, or adhesives. The bonded warp yarn ends are then trimmed back by an appropriate amount so that the yarns terminate at about the last bond point. In one embodiment, the weft yarns beneath the bonded warp ends may be of a smaller effective cross-sectional size (e.g. are of a smaller diameter) than those in the fabric body so that fabric caliper at the seam region where the warp yarns have been turned back and bonded remains relatively unchanged in comparison to that of the fabric body.
The invention therefore seeks to provide a seaming area for seamable end regions of a woven industrial fabric, the fabric comprising at least a first set of warp yarns interwoven with weft yarns and having free ends, the first set of warp yarns comprising at least a first group and a second group, the fabric comprising a fabric body and a first and second seamable end region each comprising a fabric edge, wherein at the seaming area
(i) the yarns of the first group pass around and in contact with the fabric edge, and the yarns of the second group pass around the fabric edge to form a plurality of loops protruding from the fabric edge; and
(ii) the free ends of each of the warp yarns of the first set are bonded to yarn material of the fabric body, the yarn material being selected from surfaces of the warp yarns of the first set, surfaces of the weft yarns, and combinations thereof.
The invention further seeks to provide a woven industrial fabric comprising at least a first set of warp yarns interwoven with weft yarns and having free ends, the first set of warp yarns comprising at least a first group and a second group, the fabric comprising a fabric body and a first and second seamable end region each comprising a fabric edge, wherein at the seaming area
(i) the yarns of the first group pass around and in contact with the fabric edge, and the yarns of the second group pass around the fabric edge to form a plurality of loops protruding from the fabric edge; and
(ii) the free ends of each of the warp yarns of the first set are bonded to yarn material of the fabric body, the yarn material being selected from surfaces of the warp yarns of the first set, surfaces of the weft yarns, and combinations thereof.
In the seaming areas of the invention, and in woven industrial fabrics of the invention, the preferable and advantageous features include the following.
Preferably the fabric comprises at least first and second sets of warp yarns interwoven with the weft yarns in first and second layers, and the yarn material is selected from surfaces of the warp yarns of the first set, surfaces of the warp yarns of the second set, surfaces of the weft yarns, and combinations thereof. More preferably, in fabrics comprising two layers of warp yarns, the first and second sets of warp yarns are provided as stacked pairs such that each yarn of the first set is stacked with a yarn of the second set in a vertical plane through the fabric, and each yarn of the second set is stacked with a yarn of the first set in a vertical plane through the fabric, and the yarn material is selected from surfaces of the warp yarns of the first set, surfaces of the warp yarns of the second set, surfaces of the weft yarns, and combinations thereof.
Preferably, the yarns of the first group are alternated with the yarns of the second group, such that the loops in a first seaming area at the first seamable end region are interdigitatable with the loops in a second seaming area in the second seamable end region, and the loops when interdigitated are alignable to receive a seam closure means selected from a pintle and a coil.
Preferably, the free ends of each of the warp yarns of the first set are bonded to the yarn material by a bonding step selected from at least one of laser welding, ultrasonic welding, application of an adhesive, and application of chemically reactive materials. Optionally, in fabrics comprising two layers of warp yarns, the free ends of the warp yarns of the second set are secured to surfaces of selective ones of the weft yarns.
Preferably, selected weft yarns adjacent the seam area have an effective thickness in a vertical plane through the fabric which is less than the thickness of the remaining weft yarns in the fabric body, such lesser thickness having a value (D−N) wherein D is the thickness dimension of the remaining weft yarns in the fabric body, and N is the thickness dimension of a selected one of the warp yarns. To provide such reduced effective thickness, the selected weft yarns may be constructed as hollow yarns, or as multifilament yarns, or cabled monofilament yarns. Alternatively, the selected weft yarns are constructed of a material comprising a heat-softenable and deformable polymer.
Preferably, the warp yarns of the first set have a substantially rectangular cross-sectional shape; and in fabrics comprising two layers of warp yarns, preferably the warp yarns of both the first and the second sets have a substantially rectangular cross-sectional shape.
The invention further seeks to provide a method of providing a seaming area to a woven industrial fabric, the fabric comprising at least a first set of warp yarns interwoven with weft yarns to provide a fabric body and a first and second seamable end region each comprising a fabric edge, the method comprising the steps of
(a) dividing the warp yarns of the first set proximate each of the fabric edges into at least a first and a second group;
(b) turning the yarns of the first group at the respective fabric edge to pass around and in contact with the fabric edge;
(c) turning the yarns of the second group at the respective fabric edge to pass around the fabric edge to form a plurality of loops protruding from the fabric edge; and
(d) bonding free ends of each of the warp yarns of the first set to yarn material of the fabric body, the yarn material being selected from surfaces of the warp yarns of the first set, surfaces of the weft yarns, and combinations thereof.
The method of the invention is particularly advantageous where the fabric comprises at least first and second sets of warp yarns interwoven with the weft yarns in first and second layers, and wherein the selecting of the yarn material in step (d) comprises selection from surfaces of the warp yarns of the first set, surfaces of the warp yarns of the second set, surfaces of the weft yarns, and combinations thereof. In such fabrics, preferably the first and second sets of warp yarns are provided as stacked pairs such that each yarn of the first set is stacked with a yarn of the second set in a vertical plane through the fabric, and each yarn of the second set is stacked with a yarn of the first set in a vertical plane through the fabric, and the yarn material is selected from surfaces of the warp yarns of the first set, surfaces of the warp yarns of the second set, surfaces of the weft yarns, and combinations thereof.
Optionally, in fabrics comprising two layers of warp yarns, the method further comprises, before step (b), the step of securing free ends of the warp yarns of the second set to surfaces of selective ones of the weft yarns.
Preferably, the dividing in step (a) is performed such that the yarns of the first group are alternated with the yarns of the second group, such that the loops in a first seaming area at the first seamable end region are interdigitatable with the loops in a second seaming area in the second seamable end region, and the loops when interdigitated are alignable to receive a seam closure means selected from a pintle and a coil.
Preferably, the bonding of step (d) comprises a method selected from at least one of laser welding, ultrasonic welding, application of an adhesive, and application of chemically reactive materials.
Preferably, the method further comprises, before step (a), the step of
(a.0) providing selected weft yarns adjacent the seam area having an effective thickness in a vertical plane through the fabric which is less than the thickness of the remaining weft yarns in the fabric body, such lesser thickness having a value (D−N) wherein D is the thickness dimension of the remaining weft yarns in the fabric body, and N is the thickness dimension of a selected one of the warp yarns. To provide such reduced effective thickness, the selected weft yarns may be constructed as hollow yarns, or as multifilament yarns, or cabled monofilament yarns. Alternatively, the selected weft yarns are constructed of a material comprising a heat-softenable and deformable polymer.
Preferably, the warp yarns of the first set have a substantially rectangular cross-sectional shape. In fabrics comprising two layers of warp yarns, preferably the warp yarns of both the first and the second sets have a substantially rectangular cross-sectional shape.
The invention further seeks to provide a method of forming a seam for a woven industrial fabric, comprising the steps of
(a) weaving the fabric on a loom;
(b) providing at each seamable end of the fabric a seaming area by the method of the invention; and
(c) bringing the seamable ends of the fabric together and securing them in the seam.
Optionally, step (b) can be performed while the fabric is on the loom; alternatively, before step (b), the method comprises removing the fabric from the loom.
As used in the following discussion, the terms “top”, “bottom”, “left”, “right”, “up” and “down” refer to orientations or directions in the illustrations only; the seams resulting from the joining of seaming areas of this invention may be formed with the warp yarns terminating on either the “top” or “bottom” of the fabric as it will be used on the machine for which it is intended.
The term “float” in relation to the warp yarns refers to a region where a warp yarn passes over two or more consecutive weft yarns in the weave pattern.
Further, references to known and conventional methods of seaming fabrics for which the present invention is suitable should be understood in relation to the general discussion above of the prior art with reference to
Referring first to
In the seaming area shown in
As will be apparent to those skilled in the art, when forming a seaming area in accordance with the teachings of the present invention, the retainer loops 300 would have to be created before the seaming loops 200. As can be seen from
Referring to
As can be seen from
Referring now to
In the fabric shown in
a) The warp yarns forming both the seam loops and retainer loops are terminated at differing distances back from the last weft yarn in the fabric. This is not necessary, and for some applications it may be desirable to terminate them at the same distance back, at random locations or at least at differing distances from the last weft to minimize discontinuities and improve or maintain seam strength.
b) The warp yarns forming the seam and retainer loops are bonded over warp yarn floats in the regions 263, 265 or 267 which are formed by one or two repeats of the weave pattern on the top surface. The preferred number of floats will depend on the particular application, but in general the bonding will preferably be made over one, three or more floats depending on the prevailing conditions in the machine for which the fabric is intended.
c) The warp yarns 215, 315 on the top surface 150 of the fabric and in direct contact with the weft yarns 240, 250 may also be bonded to those weft yarns 240, 250 so as to secure the warp yarns 215, 315 in place. The lower warp yarns 210, 310 are then folded around the fabric end forming retainer and seam loops 300, 200 and each is then bonded in turn to the already secured warp yarn.
d) The preferred bonding method used to secure the warp yarns at the seam area is laser welding. If the warp yarns contain carbon black or other suitable materials that absorb laser energy, then it is not necessary to use a “primer” or any other energy absorbing material to affect a weld. However, if the yarns are effectively transparent to laser energy, then it may be necessary to use a primer such as ClearWeld® or other similar material. Alternate bonding methods that may be suitable include: ultrasonic welding of the yarn components, application of an adhesive to the appropriate yarn components or the use of chemically reactive materials which react with the yarn polymer to effectively melt and allow bonding.
As shown in
t=N+N+D1=0.26+0.26+1.0=1.52 mm.
It will be appreciated that the area where the two warp yarns 210, 215 in
Alternatively, instead of using yarns of a reduced thickness, the effective cross-sectional size can be reduced where required by using hollow yarns, such as are known from U.S. Pat. No. 5,597,450 (Baker et al.) which conventionally have, but are not limited to, a solid fraction of from about 60-75%. An embodiment using such yarns is shown in
As a further alternative, the effective cross-sectional size can be reduced by the use of multifilament yarns or cabled monofilaments, which can be selected to be compressible in a similar manner as hollow yarns. An embodiment using such yarns is shown in
As a still further alternative, the effective cross-sectional size can be reduced by the use of heat softenable yarns. These are preferably generally polymeric blends (for example as disclosed in U.S. Pat. No. 6,828,261 to Soelch et al.), or sheath core bi-component yarns which have a relatively soft interior component, or single polymeric component yarns which deform under heat and pressure.
In each of
Although the seams of the present invention could be formed in a woven structure while the fabric is still on the loom, in most cases, because of factors including the dimensional changes from the conventional heatsetting process, it will be necessary to heatset the fabric before preparing and providing the seams of the invention to the fabric, preferably in the manner below.
For conventional heatsetting, following weaving, the fabric ends are stitched together to render it endless for heatsetting, a process which involves passing it around one or more rotating heated rolls while under tension to soften the yarns and thus set their crimp. This assists in rendering the fabric dimensionally stable so that it can run reliably at a high speed. Once the fabric has been heatset as required, it is removed from the heatsetting frame and the position of the eventual final fabric seam is determined.
The fabric is then prepared for seaming by removing the existing weft yarns from proximate the seaming edge back towards the fabric body a predetermined distance. This releases the warp yarns and forms a fringe area, in which the warp yarns are trimmed back a desired distance and in place of some or all of the weft yarns previously removed, preferably either smaller diameter, hollow yarns, or multifilament/cabled monofilament yarns, or yarns constructed of a material comprising a heat-softenable and deformable polymer, or a combination of such properties, are inserted. This allows the fabric ends at the seam area to later be compressed if necessary to maintain fabric caliper at the seam region consistent with the caliper of the fabric body, thus reducing or avoiding discontinuity.
All of the warp yarn ends are subjected to a combination of heat and pressure so as to restore them substantially to the pre-heatsetting uncrimped shape, i.e. to remove the crimp imparted during heatsetting.
A first group of selected, preferably alternate, warp yarns from each of the fabric edges is bent, or turned back towards the fabric body. This is most easily done by temporarily attaching the selected yarns to e.g. a yarn holder device such as a tie bar, which is laid across a group of the warp yarns. This allows the manufacturer to handle and turn or bend the selected yarns as a group. The yarns are then brought back around a selected last weft at the fabric edge, either over the PS or MS of the fabric, as desired. The tie bar and yarns are pulled back under tension and laid across the selected fabric surface.
The free end of each warp is then bonded back onto selected warp yarns within the weave of the fabric body at selected, preferably flat, surface areas such as warp yarn floats; or to selected weft yarns. A laser, or ultrasonic welding device, or similar bonding means is then brought into proximity of the warp yarns at the selected locations, thereby bonding each of the free warp yarn ends to the respective yarns in the fabric weave. Excess yarn materials at the edge of the bonding locations are cut or severed so that any surplus material is minimized in this region. This first group of selected warp yarns thus forms the retainer loops of the seam region which secure and retain the last weft at the fabric edge in position.
A spacer element having a cross-sectional shape and size to correspond generally with the shape and size of a pintle or coil which will eventually be used to close the final fabric seam is then brought into proximity of the seam face where the retainer loops have been formed, against the exterior surface of the first group of warp yarns where they are folded over the last weft yarn at each fabric edge.
The remaining group or groups of warp yarns are each attached to a yarn holder device such as a tie bar, in a similar manner to the attachment of the first group, and each group in sequence is then bent back around the spacer under tension and toward the fabric body. The free ends of the yarns of each group are then bonded to the respective yarns in the fabric weave at selected, preferably flat, surface areas such as warp yarn floats in a manner similar to that used for the first group of warp yarns which formed the retainer loops. This forms the seaming loops on each end of the fabric; the seaming loops are sized (as a result of the spacer) so as to form a channel which is sized appropriately for the selected joining means that will be used to close the final seam, for example to correspond in shape and size to that of a pintle.
The two fabric ends are then brought together and their seaming loops interdigitated, and the seam is then closed by inserting a pintle or other joining means through the channel formed by the seaming loops.
The seam area is then pressed using heat and pressure so as to reduce fabric caliper at this region and render the seam area continuous in thickness with the fabric body. The seam area is inspected and any loose warp ends are further bonded as required. The area may be sanded or otherwise abraded to minimize or remove any discontinuities that may snag or catch stationary elements in the papermaking machine, or mar the product being transported by the fabric.
The methods of the invention are applicable to forming a seam in any industrial textile, but are particularly suitable for use in fabrics which include monofilament yarns of generally flat or rectangular cross-sectional shape and which are arranged in the machine direction of the fabric such as are described by Buchanan et al. in U.S. Pat. No. 4,209,290 or Lee in U.S. Pat. No. 5,103,874.
Other fabrics containing flat, oval or elliptical warp yarns can be used also, as can round yarns, but fabrics woven using generally flattened yarns as the warp or MD components are preferred due to the higher contact area that can be achieved at the bond.
To form the reinforced seam of the present invention while the fabric is still on the loom, for a fabric having two sets of warp yarns, two warp beams are used to provide yarns for each of the first and second surfaces of the fabric. When the fabric has been woven to the desired length, the reed of the loom is allowed to “beat up” the last weft yarns several times to ensure that they are tightly packed in the fabric and as stable as possible. A laser welding device is brought into proximity of the warp on the last several repeats of the weave pattern on the first surface. The warp yarns are exposed to laser energy along the last weave repeat across the fabric width so as to bond them securely to the weft on this surface. The warp yarns are then carefully cut at or proximate to the last weft yarn at the fabric edge. The warp located on the second surface of the fabric will be used to form the seaming and retainer loops. Alternate warp yarns from the second surface are cut at a distance removed from the fabric edge, and then folded around the fabric edge and bonded in place on top of each of the already bonded warp yarns on the first surface to form the retainer loops. A spacer of suitable size is brought into position at the fabric edge and the remaining warp yarns are folded back over it and then bonded in place beside the warp yarns forming the retainer loops so as to create the seaming loops. Excess yarn material from the seaming and retainer loops is then removed and the opposing fabric edge is then seamed in a separate operation, following which the two opposing fabric edges can be brought together, and the seaming loops interdigitated to form a channel 235, and to allow the two edges to be joined by a pintle or coil.
Number | Date | Country | Kind |
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0915044.2 | Aug 2009 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CA2010/001330 | 8/27/2010 | WO | 00 | 2/1/2012 |