A rapid mechanical durability test for reinforced fuel cell membranes

A rapid mechanical durability test for reinforced fuel cell membranes

An in situ accelerated mechanical stress test (ΔP-AMST) that applies relative humidity (RH) cycling combined with a pressure differential (ΔP) at a high temperature is proposed to accelerate mechanical degradation in all types of reinforced membranes used in fuel cells and obtain mechanical failure...

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Bibliographic Details
Main Authors: Alireza Sadeghi Alavijeh, Sandeep Bhattacharya, Owen Thomas, Carmen Chuy, Erik Kjeang
Format: Article
Language:English
Published: Elsevier 2020-04-01
Series:Journal of Power Sources Advances
Subjects:
Fuel cell
Membrane
Stress
Fatigue
Durability
Relative humidity
Online Access:http://www.sciencedirect.com/science/article/pii/S266624852030010X
Description
Summary:An in situ accelerated mechanical stress test (ΔP-AMST) that applies relative humidity (RH) cycling combined with a pressure differential (ΔP) at a high temperature is proposed to accelerate mechanical degradation in all types of reinforced membranes used in fuel cells and obtain mechanical failure in a relatively short time. For validation, ePTFE reinforced membranes are mechanically degraded by RH cycling accelerated by means of a ΔP applied from cathode to anode using a custom designed polycarbonate spacer. Reinforced membrane failure detected by ΔP loss is reached within ∼10 to 10,000 RH cycles using this method, depending on the level of applied ΔP. The ΔP-AMST protocol is hence demonstrated as a fast, economical in situ alternative compared to existing methods for evaluating the mechanical fatigue durability of advanced fuel cell membranes.
ISSN:2666-2485

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