| plain weave: | twill weave [NRLP]: | 5-harness satin weave [NRLP]: |
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| Composites Design and Manufacture (BEng) - MATS 324 Reinforcement fabrics |
Contents of this page:
Woven fabrics normally consist of two sets of interlaced orthogonal fibres produced on a loom. When used for the reinforcement of composites, these textile fabrics are normally woven in one of the three styles represented below. [NRLP] indicates Figures drawn by Neil Pearce.
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Crimp is defined [1] as "the waviness of a fibre" and is normally expressed numerically as either "the number of waves or crimps per unit length" or "the difference in distance between points on the fibre as it lies in a crimped condition and the same two points when the fibre is straightened under suitable tension". The mechanical properties of composites reinforced with these fabrics increase as the crimp decreases, but drape and in-plane permeability normally decrease as the crimp decreases. See the Carr Reinforcements website for a comparison of the properties of different weave styles.
To improve the in-plane permeability of twill or satin fabrics, flow-enhancement tows (FET) may be introduced as in, for example, Hexcel Injectex fabrics:
| 5-harness satin weave with flow enhancement tows, (eg Brochier Injectex) [NRLP] | optical micrograph of Injectex fabric reinforced composite | digitally enhanced partial cross-section
of the composite micrograph [by Paul Russell - PMS] |
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The colour-coded image shows the normal horizontal tows normal to the plane of the image (green), one flow-enhancing tow normal to the plane of the image (blue) and transverse tows (red). Note the lenticular shape of the normal tows, the elliptical shape of the flow-enhancing tow and the large resin rich area adjacent to the flow-enhancing tow. An alternative approach to flow-enhancement was developed in a collaboration between Carr Reinforcements and the University of Plymouth (EPSRC Grant GR/K04699). The effect of fibre clustering and the consequent resin-rich regions is discussed under mesomechanics.
A fabric with an equal number of weight of tows in the two orthogonal directions is described as balanced. For some applications, the majority of fibres may be oriented in one direction (usually the warp for structural reasons) with a small quantity of lighter fibres at 90° (usually the weft) to produce a unidirectional fabric. There is no definitive transition point from an unbalanced fabric to a unidirectional fabric with figures of between 75-90% [2a], 80% or more [2b] or at least 95% [2c] used for the fibre weight in the principal direction. An alternative definition is "A fabric having reinforcing fibres in only one direction" [3].
Whilst the vast majority of woven reinforcements are in the form of two-dimensional planar fabrics with orthogonal fibres, it is also possible to produce triaxial weaves (fibres at 0, ±60°). There is increasing interest in 3-D textile reinforcements which find application primarily as preforms for Liquid Composite Moulding processes. Bogdanovich and Mohamed [4] have published a well-illustrated review of three-dimensional reinforcements in which they make a clear distinction between 3D interlock weave (either layer-by-layer or angle-interlock, with binder fibres crossing more than one tow) and 3D orthogonal non-crimp weave (with binder fibres running at 90° to the two other sets of tows).
| Layer-to-layer interlock 3D weave | Angle-interlock 3D weave | Orthogonal non-crimp 3D weave | ||
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| Images are reproduced from reference [4] by kind permission of Alexander Bogdanovich at 3TEX Inc. | ||||
Braiding is defined by the Textile Institute [1] as "the process of interlacing three or more threads in such a way that they cross one another and are laid in a diagonal formation. Flat tubular or solid constructions may be formed in this way". A typical braiding machine operates using a "maypole" action whereby half of the yarn carriers rotate on a clockwise path whilst weaving in and out of the remaining 50% of the yarn carriers which are following a counter-clockwise path. In the tubular braided reinforcement, each fibre follows a helical path around the principal axis of the braid. Ayranci and Carey [5] have reviewed the use of 2-D braided composites for stiffness critical applications.
The modelling of the mechanical properties of textile braids has been considered by a number of authors [e.g. 6-10].
The A&P Technology website includes a
page of Braid Basics and a
Braid Calculator.
Video of the automated production by braiding of the A-pillar for the Lexus
LFA sports car.
The Eurocarbon website includes a
section on overbraiding
including a movie (WARNING:
7.16 MB, 1 min 12 sec, MPEG format) of the process.
Weft-Insertion Warp-Knit or Warp-Insertion Weft-Knit (WIWK)
Bellara [11] states that "yarn in a knitted fabric follows a meandering path forming symmetric loops". This produces a fabric with more elasticity (more easily stretched) than woven counterparts. The fabric is considered to consist of courses (the horizontal row of loops) and wales (the vertical lines). In warp knitting each stitch within a row has a separate thread, while in weft knitting there is one yarn per row. Warp knitting is harder to unravel, while weft knitting produces more elastic fabrics.
Raz [12] considers warp knitting to be by far the most versatile fabric production system in textiles. Warp knitted fabrics can be produced flat, tubular or three-dimensional, to be elastic or stable, and with an open or closed structure. Fabric width can be over 6 m wide without seams (or a multiple of this width if it is a net construction). Warp knitting machines are divided in two categories: tricot machines and Raschel machines. Raschel machines are normally used for the production of technical textiles. Stitch-bonding machines are regarded as a special form of warp knitting machines, especially suited for the manufacture of technical textiles, non-wovens and composites. The principle of weft insertion in warp knitting involves the insertion of the reinforcement fibres in parallel across the whole width of machine. According to Raz [12], the advantages of weft insertion systems are:
Stitched fabrics use a lightweight fibre as a loop (left-hand figure below)
sewn or knitted around the reinforcement tow to create the fabric (photograph of a real reinforcement at centre figure below).
The fabrics may be just a single layer, or multiple layers as either biaxial (0°/90° or ±45° cross-plied) or multi-axial (e.g. 0°/45°/-45°/90°).
The reinforcement tow remains aligned in the plane without crimp (so these reinforcements are commonly referred to as non-crimp fabrics (NCF)).
In consequence, they have the potential for a higher fibre orientation distribution factor than for a woven fabric and each layer can pack as a unidirectional
with the possibility of higher fibre volume fractions (see photograph of a
cross-section at right-hand figure below). It is important that full consideration is given to selection of the stitching fibre as poor
resin penetration or a poor bond to this thread could be a precursor to laminate failure.
| detail of the stitch | photo of real fabric with zigzag stitches | cross-section of laminate |
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Adhesively-bonded reinforcements
There are a variety of "reinforcements" in which the fibres are held together by an adhesive or polymer ranging from those held together with a small proportion of binder through semi-preg to fully pre-impregnated (pre-preg) materials. These include:
References
Further Reading