The present invention involves a Bi-axial Bias weaving machine and two dimension woven structures (material) having interlaced bias strands. The material includes plain, twill and satin structures made of two bias flat strands (tape) interlacing each other at particular angles (30-60). The weaving machine includes bias holders assembly, chains, bias rapiers and take-up assembly. Each Bias holder is responsible for holding the flat bias strand and shedding in order to produce the desired structure such as plain, twill and satin. Chain holds the bias holders assembly and rotate in order to make production continuous. Rapier is mean to insert the bias strand into the shed produced by Bias holders assembly. Bias strand feeding set-up is connected with rapier assembly. The embodiment of this invention may be utilized to produce high performance fabrics such as textile performs for aerospace composites.
The present invention relates to weaving machine designs for biaxial bias fabric (BBF) manufacturing for Fibre Reinforced Composites. The BBF comprises two sets of bias strands interlaced with each other at bias angle. Both bias strands are fed at opposite directions, meet at center point of fabric and make biaxial bias fabric by interlacing with each other.
Bias strand is meant as an assembly of continuous filaments in the form of tow or tape. Bias angle of strand is meant the direction of the strand interlacement at angles 30° to 60°.
Textile composites are well known to several applications such as automotive, marine, transportation, civil infrastructure and off-shore due to high strength to weight ratio. Textile composites are made of textile preform consolidated with resin. Strand orientation in textile preform has great influence on properties of preform in terms of strength in one or more directions and suitability of shaping. In order to satisfy the strand orientation requirements at bias angles such as 45°, conventional woven fabrics are cut at oblique orientation and this cut piece fabric is referred as bias fabric. Such method has several drawbacks including intensive labour cost, huge wastage and compromised mechanical properties.
In W.I.P.O. Patent No. 2010/004284 A1, there is a disclosed machine relating to a method of weaving a multi-axial fabric and a loom for weaving a multi-axial fabric. This method comprises 4 layers in a woven fabric. The first layer is a bias structural layer at +45° direction, the second layer is a bias at −45° direction, third layer is weft yarn at 90° direction and finally binder yarns and warp yarns are at 0° direction. The binder yarn is the only yarn which binds all other yarns. Each binder yarn is guided with guide members in order to make the shed and beat-up the weft yarn. Rapiers are used to insert these weft yarns. During continuous operation of loom, rotating wheel feed assemblies carry bias packages. These packages release bias yarns engaged with moveable plates in order to make bias structure.
In one form of bias yarn traversing device disclosed in U.S. Pat. No. 5,137,058, the method aims to weave fabric which includes a warp layer, bias threads and a vertical thread arranged in a thickness wise direction of the fabric such that it perpendicularly intersects the warps. The fabric structure contains a bias thread layer that is composed of a large number of continuous bias threads which are arranged symmetrically to each other. Each pair of bias thread layer makes a set. The engaging positions of the bias threads are moved by a predetermined pitch in opposition direction to each other. Such movement of the engaging position and insertion of vertical threads are performed alternately. Bias yarns are engaged by screw shafts which rotate and move to and from to move the bias thread with the help of grooves of screw. There is a tendency of the yarn to slip form grooves. Here, as the bias yarn reaches the edge of the fabric, it is folded downward and travels back to the opposite edge. Such folding causes non-uniformity.
The cloth is woven with two sets of strands 2 and 3 which are interlaced with suitable weave design such as plain, twill or satin. The strands 2 and 3 extend along respective directions +X and −X which are oblique relative to the direction of length L. The directions +X and −X are preferably symmetrical and can vary between 30° to 60°, however ±45° direction is preferred for following detailed description for reference purpose.
According to another characteristic, the strands 2 and 3 are of finite length and are interfered with selvedges la and lb. The individual strands 2 and 3 can be made of any suitable material such as glass, kevlar and carbon fibres. The selvedges la and lb can be made of suitable coated material 4 or made of cords. The suitable coated material is applied during manufacturing of BBF at both sides 1a and 1b in order to hold the cut ends of strands 2 and 3 firmly.
The cloth 1 of width W can be manufactured equivalent to width of cloth made on any conventional weaving machine. According to crucial and essential characteristics in the meaning of invention, the cloth 1 is interlaced with two sets of strands 2 and 3 none of which has any joint, twist or knot. The strands 2 and 3 are straight, wider in width and flat in shape; both strands remain flat under all manufacturing circumstances and have no twist over the length 1 of cloth 1. The manufacturing process is continues and length L of cloth 1 is indefinite.
In this way newly bias strand 2 and 3 are inserted into sheds 200 and gripped by first bias holder 111 and 161 respectively by sequence. As both rotary chains 101 and 151 are connected with each other, thus movement in driving chain may lead to exact distance traveled by both rotary chains 101 and 102. Because of this, both rotary chain 101 and 151 may move exactly same distance with same timing. During the movements of these rotary chain 101 and 151, receiving heads 302 of take-up assembly 301 will also move with same distance on take-up stand with same timing. It is important to synchronize the movement of rotary chain 101 and 151 and receiving heads 302 otherwise it may lead to slackness in BBW fabric 1 and create the problems for other operations during manufacturing.
It is an object of present invention to provide the weaving machine which permits the manufacturing of two dimensional (2D) structure of bi-axial bias woven fabric. An exemplary weaving machine includes bias holders assembly, chains, bias rapiers and take-up assembly. The apparatus includes a plurality of bias holders, each of which holds bias strand under tension. The bias holder further separates the sheet of bias strands into two layers in order to insert the opposite bias strand by rapier. At least one bias holders set is configured in a vertical position above the shed and at least on bias holders set is configured in a horizontal position below the shed. The same action is conventionally carried out by heald frames in conventional weaving machine.
The apparatus further includes two continuous chains holding a bias holder at each pitch of both chains. These chains rotate at intermediate motion and make the BBF production continuous. Both chains can be operated separately or jointly.
Two rapiers are adopted to fill the gap created by two layers of bias strands. The rapiers also perform the function of beat-up in some way. First rapier enters into gap of layers of bias strand and then handover the tail of bias strand to take-up assembly. While returning, it changes its position and come closer to last inserted bias strand and then transfer the head of bias strand to bias holder. The apparatus also comprises the take-up assembly. Tail of every bias strand is gripped by take-up assembly through any means such as sticking strip, gripping holder etc.
In another aspect, invention includes biaxial bias woven fabric which consists of two sets of bias strands interlaced with each other at bias angle. The bias angle may vary between 30° to 60°, however in order to manufacture the quasi-isotropic reinforcement for composite material, bias strands are oriented at ±45° direction. The biaxial bias fabric may be manufactured with different common structures such as plain, twill and satin. It is to be understood that foregoing general description and following detailed description are exemplary, but are not restricted, of the invention.