Pressure Vessels & Piping Conference


Prague, Czech Republic

July 15-20, 2018

July 16-18, 2018

Program - Workshops


EPRI Expert Workshop on Creep Continuum Damage Models for Structural Mechanics

EPRI Expert Workshop on Creep Continuum Damage Models for Structural Mechanics in Collaboration with ASME PVP, 2018

EPRI Workshop PVP 2018 Agenda

July 19-20, 2018


We look forward to welcoming you to the 2018 Workshop. This meeting will cover State of the Art presentations regarding Creep Continuum Damage Mechanics. It is apparent that a CDM framework is particularly attractive to establishing relevant models which describe the creep behaviour of advanced steels. Particular benefits of this approach are derived for metallurgically complex steels because, for the components and loading scenarios in which they are used, there is an emerging reality that performance cannot simply be explained on the basis of strength, i.e. using deformation dominated expressions. Thus, it is apparent that creep damage susceptibility and ductility must be understood and properly considered in the models to reduce uncertainty and minimize the risks of fracture during service.

This Workshop will build on previous discussions which have considered the principles and requirements that should be followed to establish robust and relevant creep-continuum damage mechanics constitutive models. The three key requirements which should be embodied in a suitable model have been identified as:

  1. Physically Informed:
    • Provide "physically reasonable" responses for relevant stresses and temperatures,
    • Activation energies, stress exponents and other parameters should have reasonable values,
    • State variables representing key aspects of the material response should be related to underlying physical (metallurgical) mechanisms, and
    • Multiaxial forms should represent the underlying deformation and damage phenomena
  2. Convenient Mathematics:
    • Key features of the creep response (creep rate, rupture time, etc.) should be readily derived
    • Scalable for use in applications from simple calculations (e.g. constant stress) to complex finite element models, and
    • Overall representation of the material response which can be simplified for specific cases by switching on or off features of the model
  3. Pragmatic approach to Data fitting:
    • A relevant, but minimal number of vital coefficients (consistent with physical meaning),
    • Easy-to-determine coefficients without the need to adopt complex regression, and
    • Simple scaling to represent upper/lower bounds on material response by considering both strength and damage susceptibility.

    In addition to discussion of a framework for model development, review presentations considered alloy specific applications of Continuum Damage Mechanics (CDM). The meeting sessions included:

  4. Metallurgical Factors affecting high temperature performance for both Tempered Martensitic and Austenitic Stainless Steels with emphasis on:
    • Pedigree of parent metal, including documenting factors which contribute to deformation and damage,
    • Metallurgical risk factors identified relating to variability in the as-fabricated condition and which influence changes in service performance,
    • Assessment of metallurgical risk factors in multiaxial tests, and
    • Characterization of damage in parent metal and cross-weld creep tests
  5. Evaluation of established Continuum Damage Mechanics methods and potential developments with a view to seeking a unified approach for:
    • Accommodating microstructural influences on deformation and damage,
    • Describing alloy specific susceptibilities to the initiation and growth of damage
    • Incorporation of stress state effects,
    • Assessment of validity of the selected model by considering trends in behaviour established independently to the results used in model development.
  6. Design by Rule compared to Design by Analysis:
    • Options for design-by-analysis
    • Application of design-by-analysis to susceptible component geometries
    • Complexity – balancing need and simplicity

For further information and to express interest in making a presentation, please contact Jonathan Parker at ebenton@epri.com.

1st International Workshop on Risk and Resilience of Industrial installations Against Natural Threats and Mitigation Strategies

1st International Workshop on Risk and Resilience of Industrial installations Against Natural Threats and Mitigation Strategies – In collaboration with ASME PVP2018

Hilton Prague

Prague, Czech Republic, 19-20 July, 2018


Contact Person
Fabrizio Paolacci
Roma Tre University
Department of Engineering
Via Vito Volterra 62, 00146
Rome, Italy
Ph: +39 06 5733 6418
Mobile Ph: +39 329 0570703 |
E-mail: fabrizio.paolacci@uniroma3.it



The tremendous impact of natural hazards, such as earthquakes, tsunamis, flooding, etc, which triggered technological accidents, referred to as natural-technological (NaTech) events, was demonstrated, for instance by the recent Tohoku earthquake and the following Fukushima disaster in 2011 or by the UK’s 2015 winter floods which topped £5bn, with thousands of families and businesses that faced financial problems because of inadequate or non-existent insurance. The NaTech problem is quite relevant as up to 10% of industrial accidents, involving the release of Chemical, Biological, Radiological, Nuclear and high yield Explosives (CBRNE) substances, were triggered by natural hazards. To implement and support the Seveso II Directive 2012/18/EU which regulates the control of major accident hazards involving dangerous substances, XP-RESILIENCE intends to establish a network of individual research projects working towards

Advanced Modelling and Protection –via metamaterial-based isolators/layouts- of Complex Engineering Systems for Disaster Reduction and Resilient Communities. In this respect, this workshop has the aim to offer to students and scholars a clear overview of the problems and the available solutions and tool. With important experts on Resilience and Na-tech risk the workshop will be a unique occasion to familiarize with this hot topic and be in contact with the resilience and risk calculation community.


The main objective of this workshop is to familiarize Early Stage and Experienced Researchers with the state-of-the-art of risk and resilience of industrial installations. At the end of the course, attendants should acquire the basic knowledge concerning:

  • Basic and advanced concepts for risk and resilience calculation
  • Vulnerability analysis of the most critical industrial facility units
  • Risk analysis methods of major-hazard industrial installations
  • Resilience concepts applied to industrial facilities
  • Concepts application through case studies

For further information and to express interest to attend this event, please contact Fabrizio Paolacci at fabrizio.paolacci@uniroma3.it