Non Circular /Profile fibres
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Fibres with non-circular cross-section and hollow fibres
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The cross-section or geometry of melt spun fibre essentially depends on
the design of spinneret holes through which the initial extrusion takes
place. Synthetic fibres such as polyester and nylon are generally
produced using spinneret with circular holes and have a circular
cross-section.While in the case of solution spinning and coagulation
process which involve mass transfer result in non-circular cross-section
even when circular holes are used.
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Why fibres with non circular cross-section?
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The
natural fibres do not have a perfect circular shape, cotton has a bean
shaped cross-section and silk has a roughly triangular cross-section.
Non-circular cross-sections are observed to result in greater lusture,
high covering power, improved handle, light-weight and warm
preservation.The non circular cross-sections of these fibres result in
excellent capillarity and wicking properties for removing moisture,
therefore are used for diapers, sanitary towels,filter media,shoe liners
and wound dressings. Therefore, filaments with non-circular
cross-sections are desirable for achieving these special effects.
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Approaches for producing non-circular fibres:
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The modified filament cross-sections result either by coalescence or
fusion of melt streams below the spinneret or directly from extrusion
through profiles capillaries.
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The major
challenge for achieving non circular fibres is spinneret design and
optimization of spinning parameters for different polymers with unique
rheological properties. The cross-sections of fibres and spinnerets used
for producing these are shown in Figure 1.
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Figure 1. The cross-sections of fibres and its spinnerets
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The
reshaping of filament along the spinline depends primarily on the time
of solidification,the longer this time period, the greater the degree of
reshaping. The factors that increase the possibility or extent of
reshaping are:
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The structural and cross sectional shape can also be changed in high-speed melt spinning.
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In general, the spinnerets orifices of diameter 0.18-0.45 mm and length
0.4-0.8 mm are used for producing circular cross-sectional shape. For
producing some other cross-sectional shapes typical dimensions and
design of spinnerets is given below.
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Trilobal
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The trilobal cross-section was the first departure from circular
cross-section and was introduced by DuPont in USA to produce lustorous
yarn and fabric.The fibres can be produced using a typical spinneret
orifice shown in Figure 2.
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Figure 2. Trilobal cross-section of fibre
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Twin
trilobal fibres resemble silk fibres and are very lustorous.These can
be produced by conjugated bicomponent spinning of trilobal cross-section
yarn.The three tips of the trilobal crosssection may consist of polymer
that is easily soluble and results in special twin trilobal cross
section ( Figure 3).
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Figure 3. Twin trilobal cross-section
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The
rectangular shaped cross-section fibres are produced using rectangular
spinnerets. A typical spinneret with dimensions and the dimensions of
the fibre produced using this are shown in Figure 4.
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Figure 4. Spinneret for fibre with rectangular cross-section
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For hollow fibre production, it is important to consider the die swell
and the spinneret dimensions are designed accordingly. A typical
spinneret with dimensions and the resulting hollow fibre with dimensions
is shown in Figure 5.
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Figure 5. Spinneret designs for hollow fibre and extruded hollow fibre
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Other methods like separation
of bicomponent fibre and thin-film splitting are also used. These are
discussed in the next chapter.
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