R. Böhme scite author profile

synopsisThe rate of decomposition of PVDC is sensitive to differences in the method of preparation of the polymer. Polymers prepared by mass polymerization of very pure monomer were most stable. Emulsion polymerized PVDC degraded the fastest. The activation energy for the latter was 34.4 kcal/mole. Over the range of 130"-190°C, the rate of decomposition increases with reaction time to -10% HCI evolved. Beyond this point, the reaction follows first-order kinetics. The first-order rate is independent of molecular weight. Lamellar crystals of PVDC degrade at a higher rate than "as polymerized" powders. This may be due in part to annealing of the crystals in the degradation temperature range; but it also results from a sensitization of the polymer to thermal degradation from exposure to the polar solvents used for recrystallization. A mechanism is proposed to account for these observations.

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Local Structure Fixation in the Composite Manufacturing Chain

Girdauskaite

Krzywinski

Rödel

et al. 2010

Appl Compos Mater

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Compared to metal materials, textile reinforced composites show interesting features, but also higher production costs because of low automation rate in the manufacturing chain at this time. Their applicability is also limited due to quality problems, which restrict the production of complex shaped dry textile preforms. New technologies, design concepts, and cost-effective manufacturing methods are needed in order to establish further fields of application. This paper deals with possible ways to improve the textile deformation process by locally applying a fixative to the structure parallel to the cut. This hinders unwanted deformation in the textile stock during the subsequent stacking and formation steps. It is found that suitable thermoplastic binders, applied in the appropriate manner do not restrict formation of the textile and have no negative influence on the mechanical properties of the composite.

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Stress relaxation of mono and polydisperse polystyrene

Tobolsky¹,

Schaffhauser²,

Böhme³

1964

J. Polym. Sci. B Polym. Lett.

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R. Böhme

Sintering of advanced ceramics using a 30-GHz, 10-kW, CW industrial gyrotron

Synthesis and dynamic compaction of ceramic nano powders by techniques based on electric pulsed power

The thermal decomposition of poly(vinylidene chloride) in the solid state

Local Structure Fixation in the Composite Manufacturing Chain

Stress relaxation of mono and polydisperse polystyrene

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