A kinetic model for predicting the oxidative degradation of additive free polyethylene in bleach desinfected water

Mikdam, Aïcha; Colin, Xavier; Minard, Gaelle; Billon, Noëlle; Maurin, Romain

doi:10.1016/j.polymdegradstab.2017.09.020

Cited by 39 publications

(29 citation statements)

References 46 publications

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“…As expected, almost all the rate constants (from k 1u to k 6d ) give similar values for EPDM and PE. 27,[57][58][59] In addition, a comparatively small difference is observed between the values of constant k 3 , for which the pre-exponential factor is about six times greater and the activation energy is about 5 kJ mol À1 greater for EPDM, no doubt because of the presence of allylic and tertiary C-H bonds in EPDM, which are believed to be more reactive than secondary C-H bonds. This small difference fully justifies the first assumption in the ''chemical level'': EPDM terpolymers with an ethylene fraction higher than 60 mol.% behave like PE.…”

Section: Resultsmentioning

confidence: 99%

Chemo-Mechanical Model for Predicting the Lifetime of Epdm Rubbers

Colin

Hassine²,

Nait-Abelaziz

2019

Rubber Chemistry and Technology

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A chemo-mechanical model has been developed for predicting the long-term mechanical behavior of EPDM rubbers in a harsh thermal oxidative environment. Schematically, this model is composed of two complementary levels: The “chemical level” calculates the degradation kinetics of the macromolecular network that is introduced into the “mechanical level” to deduce the corresponding mechanical behavior in tension. The “chemical level” is derived from a realistic mechanistic scheme composed of 19 elementary reactions describing the thermal oxidation of EPDM chains, their stabilization against oxidation by commercial antioxidants but also by sulfide bridges, and the maturation and reversion of the macromolecular network. The different rate constants and chemical yields have been determined from a heavy thermal aging campaign in air between 70 and 170 °C on four distinct EPDM formulations: additive free gum, unstabilized and stabilized sulfur vulcanized gum, and industrial material. This “chemical level” has been used as an inverse resolution method for simulating accurately the consequences of thermal aging at the molecular (concentration changes in antioxidants, carbonyl products, double bonds, and sulfide bridges), macromolecular (concentration changes in chain scissions and cross-link nodes), and macroscopic scales (weight changes). Finally, it gives access to the concentration changes in elastically active chains from which are deduced the corresponding changes in average molar mass MC between two consecutive cross-link nodes. The “mechanical level” is derived from a modified version of the statistical theory of rubber elasticity, called the phantom network theory. It relates the elastic and fracture properties to MC if considering the macromolecular network perfect, and gives access to the lifetime of the EPDM rubber based on a relevant structural or mechanical end-of-life criterion. A few examples of simulations are given to demonstrate the reliability of the chemo-mechanical model.

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Section: Resultsmentioning

confidence: 99%

Chemo-Mechanical Model for Predicting the Lifetime of Epdm Rubbers

Colin

Hassine²,

Nait-Abelaziz

2019

Rubber Chemistry and Technology

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“…Soil pollutants can diffuse through the pipe affecting the quality of drinking water (Holder et al, 2019), whilst chlorinated water as a result of using disinfectants (such as chlorine or hypochlorous acid), deteriorates the wall of the pipe through oxidation, which over time embrittles the material, resulting in crack propagation driven by internal pressure. Oxidative degradation can also occur as a result of spontaneous chemical reaction with atmospheric oxygen (Colin et al, 2009;Ghabeche et al, 2015;Mikdam et al, 2017). PVC can also deteriorate due to abiotic factors (e.g.…”

Section: Corrosion and Chemical Degradationmentioning

confidence: 99%

Improving pipe failure predictions: Factors affecting pipe failure in drinking water networks

et al. 2019

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“…• Moreover, the constants have the following order: k 4 > k 5 > k 6 , k 2 >> k 3 >> k 1 , which are in high agreement with other wide ranges of researches. [39][40][41][42]…”

Section: Modeling Resultsmentioning

confidence: 99%

Multiscale physicochemical characterization of a short glass fiber–reinforced polyphenylene sulfide composite under aging and its thermo‐oxidative mechanism

Zuo

Tcharkhtchi

Shirinbayan

et al. 2018

Polymers for Advanced Techs

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physicochemical characterization of a short glass fiber-reinforced polyphenylene sulfide composite under aging and its thermo-oxidative mechanism.In this paper, the thermo-oxidation for a short glass fiber-reinforced polyphenylene sulfide (PPS/GF) composite was experimentally and theoretically studied by a wide range of physicochemical and mechanical techniques. The accelerated thermal aging temperatures were fixed at 100°C, 140°C, 160°C, 180°C, and 200°C. Firstly, the results of weight loss under aging indicate the formation of volatile products because of chain scission of end groups. Also, Fourier-transform infrared spectroscopy (FTIR) results suggest that the formation and accumulation of carbonyl group arising from the formation of hydroperoxides in oxidative propagation process. In all cases of different thermal oxidation temperatures, it is hard to observe some significant change about the concentration of carbonyl group during the induction time. This induction time depends inversely on the oxidation temperature. Moreover, the cross-linking and chain scissions exist together according to the results of rheological results andit is easier to see the cross-linking phenomenon at the beginning of oxidation while the chain scissions are more pronounced, with the oxidation process developing further. In aspect of mechanical properties, σ max increases at the beginning of oxidation because of cross-linking, and subsequently, the σ max always decreases because of thermo-oxidation of the PPS matrix. In addition, the detailed thermo-oxidation processes are fully discussed in the end of this study. A mechanistic schema has been proposed to present different oxidation reactions of PPS polymer and then a kinetic model has been extracted from this mechanism. Afterwards, the model has been verified by experimental results at different temperatures.

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A kinetic model for predicting the oxidative degradation of additive free polyethylene in bleach desinfected water

Cited by 39 publications

References 46 publications

Chemo-Mechanical Model for Predicting the Lifetime of Epdm Rubbers

Chemo-Mechanical Model for Predicting the Lifetime of Epdm Rubbers

Improving pipe failure predictions: Factors affecting pipe failure in drinking water networks

Multiscale physicochemical characterization of a short glass fiber–reinforced polyphenylene sulfide composite under aging and its thermo‐oxidative mechanism

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