1975
DOI: 10.1002/pol.1975.180130906
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Flow, high‐elastic (recoverable) deformation, and rupture of uncured high molecular weight linear polymers in uniaxial extension

Abstract: The behavior of narrow molecular weight distribution polymers has been investigated under uniaxial extension at constant deformation rate and at constant stress. It has been established that up to rupture these polymers behave as linear viscoelastic bodies. A detailed investigation of the rupture phenomenon has shown that the rupture of fluid polymers is due to their transition to the rubbery state at critical deformation rates, with the result that they disintegrate like quasi‐cured rubbers. The effect of the… Show more

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Cited by 79 publications
(39 citation statements)
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“…The imposed disturbances correspond (non-dimensionally) to the ones in figure 3. The SBR data show a large scattering, whereas the data from Vinogradov et al [1] show agreement with the calculated break, within the scattering of the measurements.…”
Section: Breakupmentioning
confidence: 53%
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“…The imposed disturbances correspond (non-dimensionally) to the ones in figure 3. The SBR data show a large scattering, whereas the data from Vinogradov et al [1] show agreement with the calculated break, within the scattering of the measurements.…”
Section: Breakupmentioning
confidence: 53%
“…Figure 5 contains the break of rectangular shaped 240 kg/mole SBR samples from Wang et al [21]. These are shown together with the first published breaking study by Vinogradov et al [1] (data from their figure 1). They extended 'dog-bone' shaped PI, with a central cylinder of length L 0 = 30 mm and a radius of R = 2.5 mm, from the ends of the sample.…”
Section: Breakupmentioning
confidence: 94%
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