In this paper, we extend the coupled environment fracture model (CEFM) for intergranular stress corrosion cracking (IGSCC) of sensitized Type 304SS in light water reactor heat transport circuits by incorporating steel corrosion, the oxidation of hydrogen, and the reduction of hydrogen peroxide, in addition to the reduction of oxygen (as in the original CEFM), as charge transfer reactions occurring on the external surfaces. Additionally, we have incorporated a theoretical approach for estimating the crack tip strain rate, and we have included a void nucleation model to account for ductile failure at very negative potentials. The key concept of the CEFM is that coupling between the internal and external environments, and the need to conserve charge, are the physical and mathematical constraints that determine the rate of crack advance. The model provides rational explanations for the effects of oxygen, hydrogen peroxide, hydrogen, conductivity, stress intensity, and flow velocity on the rate of crack growth in sensitized Type 304 in simulated LWR in-vessel environments. We propose that the CEFM can serve as the basis of a deterministic method for estimating component life times.

Subject
Environmental cracking, External surfaces, Strain rate, Crack growth, Intergranular stress corrosion cracking, Stress intensity, Aqueous environments, Tip strain, Stress cracking, Oxygen, Cracks, Stress corrosion cracking, Conductivity
Keywords:
Type 304SS, stress corrosion cracking, coupled environment fracture model, high temperature aqueous systems, nuclear reactor coolant circuits
© 1995 Association for Materials Protection and Performance (AMPP). All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means (electronic, mechanical, photocopying, recording, or otherwise) without the prior written permission of AMPP. Positions and opinions advanced in this work are those of the author(s) and not necessarily those of AMPP. Responsibility for the content of the work lies solely with the author(s).
1995
Association for Materials Protection and Performance (AMPP)
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