Laurent Cormier scite author profile

Effects of cold climate exposure on composite material structures are scarcely documented. As a result, even if exceptional wind conditions prevail in some cold regions, uncertainties related to composite materials durability at low temperatures may hinder development of wind energy projects in those regions. Therefore, as part of the Wind Energy Strategic Network (WESNet) of the Natural Sciences and Engineering Research Council (NSERC) of Canada, efforts were made to evaluate the effects of cold climate exposure on the mechanical properties of glass-epoxy composites. Tensile and compressive quasi-static tests as well as tensile (R = 0.1) and fully-reversed (R = −1) fatigue tests were performed on vacuum-infused [±45] 2s glass-epoxy composites at -40 and 23 . Results for quasi-static tests show an increase of tensile, compressive and shear strengths and moduli at low temperatures. It is also demonstrated that for the stress range under scrutiny, fatigue performance is improved at −40 for both the R = 0.1 and R = −1 loading cases. Moreover, the failure mode for R = −1 fatigue changed from compressive failure due to buckling of delaminated plies to tensile failure, suggesting a more efficient use of the material. However, if R = −1 fatigue results at low temperature are extrapolated towards the very low stresses that are also part of wind turbine blades fatigue load spectrum, fatigue life may be degraded compared to that at ambient temperature. Finally, evidence of visco-elastic behaviour leading to changes in s − N curve slope parameter are reported. 1

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Ethynyl‐terminated polyethers from new end‐capping agents. II. End‐chain functionalization through nitro displacement

Lucotte¹,

Cormier²,

Delfort³

1991

J. Polym. Sci. A Polym. Chem.

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Ethynyl‐terminated polysulfones and ethynyl‐terminated polyether‐ketones were prepared in a one‐step polyetherification reaction using new end‐capping agents, respectively 4‐ethynyl‐3′‐nitrodiphenylsulfone and 4‐ethynyl‐4′‐nitrobenzophenone. These reagents were prepared according to a three‐step route each. End‐capping of the polymers involve the nitro displacement by a phenoxide ion. The nitro group was found to be more reactive than the fluoro one as a leaving group. Due to the thermally induced reaction of their ethynyl end‐groups, the polymers lead to materials with improved glass transition temperatures and good thermostability.

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Characterization of Dielectric Walls of Capacitors

Gnonhoue

Velazquez-Salazar

Millard

et al. 2020

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Modelling the effect of temperature on the probabilistic stress–life fatigue diagram of glass fibre–polymer composites loaded in tension along the fibre direction

Cormier

Joncas

2017

Journal of Composite Materials

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Predicting the fatigue performance of composites has proven to be a challenge both conceptually, due to the inherent complexity of the phenomenon, and practically, because of the resource-intensive process of fatigue testing. Moreover, mechanical behaviour of polymer matrix composites exhibits a complicated temperature dependence, making the prediction of fatigue performance under different temperatures even more complex and resource intensive. The objective of this paper is to provide a method for the prediction of fatigue life of glass-polymer composites loaded in the fibre direction at various temperatures with minimal experimental efforts. This is achieved by using a static strength degradation approach to fatigue modelling, where only two parameters (including static strength) are temperature dependent, in conjunction with relationships for these two fatigue model parameters temperature dependence. The method relies on fatigue data at a single temperature and simple static tests at different temperatures to predict the effects of temperature on the material's fatigue behaviour. The model is validated on experimental data for two unidirectional (UD) and one woven glass-epoxy composites and is found to accurately predict the effect of temperature on fatigue life of composites. A method to obtain probabilistic stress-life (P − S − N) fatigue diagrams including temperature effects is also discussed. 1

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Laurent Cormier

Effects of Cold Temperature, Moisture and Freeze-Thaw Cycles on the Mechanical Properties of Unidirectional Glass Fiber-Epoxy Composites

Effects of low temperature on the mechanical properties of glass fibre–epoxy composites: static tension, compression, R = 0.1 and R =− 1 fatigue of ±45° laminates

Ethynyl‐terminated polyethers from new end‐capping agents. II. End‐chain functionalization through nitro displacement

Characterization of Dielectric Walls of Capacitors

Modelling the effect of temperature on the probabilistic stress–life fatigue diagram of glass fibre–polymer composites loaded in tension along the fibre direction

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