The Quest for Absolute Concrete Durability Performance Criteria

Geert de Schutter

doi:10.4028/www.scientific.net/KEM.711.599

Paper Titles

Fire Performance of Columns Made of Normal and High Strength Concrete: A Comparative Analysis
p.564

Statistical Comparison of the Results of Applying Several Methods in Checking Concrete Columns’ Fire Resistance
p.572

On the Structural Behavior of Reinforced Concrete Walls Exposed to Fire
p.580

Modelling the Response of Simply-Supported Two-Way Reinforced Concrete Slabs Exposed to Fire
p.588

The Quest for Absolute Concrete Durability Performance Criteria
p.599

Achieving Concrete Durability in Chloride Exposures
p.607

Utilization of Fabric Formwork for Improving the Durability of Concrete from Supersulfated Cement
p.615

Durability Modeling for Enhancing the Service Life of a Building Constructed on a Reclaimed Land in the Sea
p.622

Evaluation of Water Permeability in Fibre Reinforced Hydraulic Lime Mortar Intended for Conservation
p.630

HomeKey Engineering MaterialsKey Engineering Materials Vol. 711The Quest for Absolute Concrete Durability...

The Quest for Absolute Concrete Durability Performance Criteria

Abstract:

Deemed-to-satisfy durability requirements, as typically provided in code prescriptions (minimum cement content, maximum water cement ratio, minimum strength class) are now approaching their limits of applicability. With the implementation of new tailor-made binder types, including a multitude of powders (reactive and even non-reactive), the prescriptive parameters cement content and water/cement ratio become unclear and do not always correlate well with the real durability performance. While the equivalent concrete performance concept (ECPC) already offers a first way out of this debate, it still fundamentally maintains durability requirements at a deemed-to-satisfy level, as the new binder type needs to be experimentally calibrated relative to a standard solution. A more fundamental solution needs to consider the absolute durability performance of the concrete applied in the real structure. This performance needs to be evaluated in laboratory conditions (potential performance) as well as on the final structure (as-built performance). However, although straightforward in principle, the quest for absolute durability performance criteria is complicated, with remaining fundamental obstacles. This paper intends to give a general overview.

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Periodical:

Key Engineering Materials (Volume 711)

Pages:

599-606

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.711.599

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Online since:

September 2016

Authors:

Geert de Schutter*

Keywords:

Concrete, Durability, Durability Criteria, Durability Indicators, Durability Performance

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