Longterm performance of polyolefins in different environments including chlorinated water: antioxidant consumption and migration and polymer degradation

Lundbäck, Marie

January 2005

The long-term performance of stabilized polyolefins in different environments was studied with focus on antioxidant consumption and migration. Plaques of linear polyethylene (LPE) and branched polyethylene (BPE) were stabilized with Santonox® R (4,4'-Thiobis(6-tert-butyl-3-methylphenol)), Irganox® 1081 (2,2’-Thiobis(4-methyl-6-tertbutylphenol)), or Lowinox® 22M46 (2,2’-Methylenebis(6-tert-butyl-4-methylphenol)). The samples were aged in water and nitrogen at 75, 90 and 95°C. Antioxidant concentration profiles were obtained by oxidation induction time (OIT) measurements using differential scanning calorimetry (DSC). The very flat antioxidant concentration profiles of the plaques exposed to non-aqueous media indicated that the migration of antioxidant to the surrounding medium was controlled by the low evaporation rate at the sample boundary. The samples of BPE and Santonox R were also exposed to air and water saturated with air. The similarity of the antioxidant concentration profiles of Santonox R obtained after ageing in air and nitrogen suggested that the fraction of antioxidant oxidized is negligible in comparison with the loss of antioxidant by migration to the surrounding media. The loss of Santonox R in samples exposed to water saturated with air was faster than for the samples exposed to oxygen-free water. This was due to increased mass transport of the antioxidant from the polymer phase boundary to the water phase when oxygen was present. An unexpected higher migration rate from LPE than from BPE was proposed to be due to the low boundary loss rate in BPE, caused by the presence of a thin liquid-like (oligomeric) surface layer developed during ageing. A quantitative relationship was found between the boundary loss rate to water and the polarity of antioxidants. The antioxidant diffusivities were approximately equal in LPE and BPE, indicating that the constraining effect of the crystals on the non-crystalline fraction did not affect the antioxidant molecules. Results obtained by liquid chromatography of extracts confirmed that the gradual decrease in OIT with increasing ageing time was due to migration of antioxidant to the surrounding medium. Pipes of high-density polyethylene stabilized with hindered phenols and phosphites were exposed to chlorinated water at elevated temperatures. OIT showed that the stabilizing system was rapidly chemically consumed by the action of chlorinated water. Size exclusion chromatography and DSC showed extensive polymer degradation strictly confined to the immediate surface of the unprotected inner wall material and to the amorphous phase of the semicrystalline polymer. The rate of growth of the layer of highly degraded polymer was constant. Pipes of isotactic polybutene-1 were pressure-tested in chlorinated water at a controlled pH, and the lifetime was assessed as a function of temperature and chlorine content. The lifetime shortening in chlorinated water was significant even at relatively low chlorine contents, 0.5 ppm. A further increase of chlorine content led to only a moderate shortening of the lifetime. The temperature dependence of the lifetime data obeyed the Arrhenius law. The decrease of the antioxidant concentration was independent of the chlorine concentration in the range of 0.5-1.5 ppm. The time to reach depletion of the antioxidant system could be predicted by linear extrapolation. / QC 20101020

Chemical engineering

polyethylene

polybutylene

HDPE

LLDPE

phenolic antioxidants

oxidation induction time(OIT)

migration

chlorinated water

pressure testing

lifetime

chemical consumption.

Kemiteknik

Chemical engineering

Kemiteknik

Analyse et modélisation cinétique de la perte physique et de la consommation chimique d'un mélange phénol/HALS au cours du vieillissement radio-thermique d'une matrice EPDM / Kinetic analysis and modeling of physical loss and chemical consumption of a phenol/HALS blend durind the radio-thermal ageing of an EPDM matrix

Bannouf, Wissam

02 December 2014

La durée de vie des isolants synthétiques de câbles électriques installés en centrale nucléaire est l'une des préoccupations majeurs d'EDF R&D. Pour répondre à cette question, un modèle cinétique de vieillissement radiothermique a été développé pour une matrice EPDM stabilisée par un mélange phénol/HALS dans cette thèse. Ce modèle est dérivé d'un schéma mécanistique d'oxydation, établi dans une étude précédente pour la matrice PE pure, mais complété par les principales réactions de stabilisation des deux types d'antioxydants. Sa validité a été vérifiée avec succès pour une matrice EPDM pure et stabilisée par 0,1, 0,3 et 0,5% w/w de chaque type d'antioxydants, mais aussi par (0-0,3), (0,1-0,2), (0,15-0,15), (0,2-0,1), (0,3-0)% w/w de mélange des deux antioxydants. Le modèle cinétique prédit de manière satisfaisante la grande majorité des courbes cinétiques de consommation chimique des fonctions phénoliques et des fonctions amines, mais aussi des courbes d'accumulation des produits carbonyles dans l'air entre 140 et 160°C en absence d'irradiation γ, mais aussi sous 0,1 kGy/h-45°C, 1 kGy/h-51,5 °C et 10 kGy/h-63,5 °C. Différentes voies possibles d'amélioration sont proposées. / The lifetime prediction of synthetic insulations of electrical cables installed in nuclear power plants is one of the main concerns of EDF R&D. To answer this question, a radiothermal ageing kinetic model has been developed for an EPDM matrix stabilized by a phenol/HALS blend in this study. This model is derived from an oxidation mechanistic scheme, established in a previous study for the neat PE matrix, but completed by the main stabilization reactions of both antioxidants. Its validity has been checked successfully for an EPDM matrix unstabilized and stabilized by 0.1, 0.3 and 0.5% w/w of each antioxidant, but also by (0-0.3), (0.1-0.2), (0.15-0.15), (0.2-0.1), (0.3-0)% w/w of both antioxidants. The kinetic model predicts satisfyingly the large majority of kinetic curves of chemical consumption of phenolic and amine functions, but also the kinetic curves of carbonyl group build-up in air between 140 and 160°C in the absence of γ irradiation, but also under 0.1 kGy/h-45°C, 1 kGy/h-51.5 °C et 10 kGy/h-63.5 °C. Various possible ways of improvement are proposed.

Matrice EPDM

Mélange phénol/HALS

Perte physique

Consommation chimique

Radio-Thermo-Oxydation

Stabilisation

EPDM matrix

Phenol/HALS blend

Physical loss

Chemical consumption

Radio-Thermal ageing

Stabilization