Science and Technology of Fibers and Related Materials: Proceedings of the Fiber Society 50th Anniversary Technical Conference Held in Princeton, New Jersey, August 19-23, 1990Ludwig Rebenfeld |
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Page 192
Proceedings of the Fiber Society 50th Anniversary Technical Conference Held in Princeton, New Jersey, August 19-23, 1990 Ludwig Rebenfeld. fiber axis [ 6-9 ] . This model is both necessary and sufficient to explain the currently ...
Proceedings of the Fiber Society 50th Anniversary Technical Conference Held in Princeton, New Jersey, August 19-23, 1990 Ludwig Rebenfeld. fiber axis [ 6-9 ] . This model is both necessary and sufficient to explain the currently ...
Page 342
... fiber in the yarn has a strain energy due to its distortion from the shape it would assume if fully relaxed and free from any forces or geometrical constraints . The space curve [ 4 ] which defines the locus of the relaxed fiber axis ...
... fiber in the yarn has a strain energy due to its distortion from the shape it would assume if fully relaxed and free from any forces or geometrical constraints . The space curve [ 4 ] which defines the locus of the relaxed fiber axis ...
Page 343
... fiber strain energies with reference to the moduli and preferred ... fiber crimp . The wetting and drying of wool yarns , for example , produces significant ... axis . This can cause either relative slippage of the fibers or extension of ...
... fiber strain energies with reference to the moduli and preferred ... fiber crimp . The wetting and drying of wool yarns , for example , produces significant ... axis . This can cause either relative slippage of the fibers or extension of ...
Contents
Technological Developments in ManMade Fibers and Related | 33 |
Morphology and Near Tm Behavior of High Performance Ultrahigh | 67 |
Properties Structures and Temperature Limitations | 87 |
Copyright | |
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amorphous analysis angle appear Applied assumed behavior bending birefringence blend braided break calculated carpet compared composite compression constant cotton crystalline crystallization curve decrease deformation density dependence described determined developed diameter diffusion direction discussed distance distribution draw effect energy experimental extension fabric factor failure fiber filament finish force fraction function geometry given heat higher impact improved increase indicated initial length liquid load lower m/min material measured mechanical method modulus nylon observed obtained occur orientation parameters phase polyester polymer possible present pressure produced properties range ratio recovery relative sample Scanning shape shear shown in Figure shows solution specimen Spectra speed spinning spun strain strength stress structure surface Table temperature tenacity tensile Text treated treatment twist unit values variability yarn