J.W. Youren scite author profile

Commercial samples of two ethylene—propylene terpolymers (EPDM), two isobutene— isoprene copolymers (IIR), one polyisobutene (PIB) and one chlorosulphonated polyethylene (CSPE) were pyrolysed at temperatures between 770 and 1370 K in a quartz micro‐furnace. Volatile products were analysed by gas chromatography using wide‐boiling‐range and high‐boiling‐point columns with flame ionisation detectors and/or online quadrupole mass spectrometry using helium as carrier. Low molecular weight gases were separated on a crosslinked polystyrene bead column and detected with a katharo‐meter using argon as carrier. Mechanisms are put forward to account for the temperature‐dependence of pyrolysis‐product yields as follows. In the primary pyrolysis (ca 770–870 K) EPDM products arise principally from 1 : 5 : 9(: 13 : 17) intramolecular hydrogen transfer accompanied by some unzipping. There is also evidence for a small amount of transfer to the third carbon atom and of some β‐scission. IIR and PIB yielded isobutene presumably by stepwise cyclic unimolecular elimination. However, a number of other products including telomers, methane, iso‐butane and neopentane are explained by telomerisation of isobutene and intramolecular transfer reactions following random scission; at 870 K, there is already evidence for some aromatisation. CSPE pyrolysis is complicated by preliminary loss of SO2Cl groups and dehydrochlorination to form a polyene. Concomitant crosslinking may involve inter‐molecular elimination of HCl and/or a Diels‐Alder type reaction between two polymer molecules which have already undergone dehydrochlorination. Subsequent thermal degradation of the main chain proceeds principally by 1 : 5 hydrogen transfer. At intermediate temperatures (above 900 K) secondary pyrolysis occurs in which higher alk‐l‐enes formed by primary pyrolysis break down to lower molecular weight products probably by a modified Rice mechanism and associated intramolecular cyclic dissociation. Similar mechanisms are proposed to explain the secondary products from IIR and CSPE. At higher temperatures (above 1000 K) further fragmentation, cyclisation and aromatisation. occur. For all the polymers, hydrogen yields increase sharply and yields of C3/C4 products diminish; C2 yields show maxima at temperatures about 1100 K. Below 1200 K, benzene is formed in largest yield. Toluene yields fall at temperatures above 1100 K, but naphthalene is formed in increasing yields up to a maximum at about 1220 K. At these higher temperatures, the product spectrum is simplified by the disappearance of molecules of intermediate size leaving only small fragmentation products and rather large polynuclear aromatics (anthracene, etc.). Two main routes are suggested for the formation of cyclic products from EPDM and IIR‐ cyclisation of (particularly) methyl‐substituted n‐alkenes/alkanes of sufficiently high carbon number; and the reaction of intermediate molecules such as olefin + diene by a Diels‐Alder reaction. At the highest temperatures investigated, high hydrogen yiel...

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Thermoanalytical studies of the pyrolysis of organic polymers

Smith

Youren

1969

Journal of Thermal Analysis

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Some applications of thermoanalytical techniques (TG and DTA) to the study of organic polymer pyrolysis are described. It is shown that in order to obtain meaningful kinetic parameters strict control of environmental conditions is required. Experimental results are given for selected ethylene-propylene co-and ter-polymers, for halogenated polymers including polyvinyl chloride and neoprene in admixture with ferric oxide, and for other materials.This paper reviews some of the work carried out at the National College of Rubber Technology on the pyrolysis of raw organic polymers and certain polymer-additive mixtures of technological importance.The ultimate thermal stability of a polymer, the mode of degradation and the influence of certain additives is of prime interest both to the polymer chemist preparing new polymers and to the technologist seeking to use a compounded polymer at elevated temperatures. ]'he studies reported here use thermogravimetry (TG) and differential thermal analysis (DTA) to characterize polymer degradation processes and it is shown that careful control of experimental conditions enables a satisfactory correlation of data from these techniques. Materials and preparation methodsThe raw polymers used were as follows:

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USA specifications for composites: (2) Federal, Military and AMS specifications for glass fibre reinforcement

Edwards¹,

Youren²

1973

Composites

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Ablative plastics

Youren¹

1971

Composites

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J.W. Youren

Ablation of elastomeric composites for rocket motor insulation

Pyrolysis of polyolefin elastomers

Thermoanalytical studies of the pyrolysis of organic polymers

USA specifications for composites: (2) Federal, Military and AMS specifications for glass fibre reinforcement

Ablative plastics

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