Industrial Application of Biological Self-healing Concrete: Challenges and Economical Feasibility

Filipe Bravo Silva; Nico Boon; Nele De Belie; Willy Verstraete

doi:10.5912/jcb662

Authors

Filipe Bravo Silva Gent University
Nico Boon
Nele De Belie
Willy Verstraete

DOI:

https://doi.org/10.5912/jcb662

Keywords:

Concrete, Self-healing, Spores, Encapsulation, Economics

Abstract

Self-healing concrete has been scrutinized by several researchers and some industrial concrete producers in relation to the remediation of the occurrence of micro-cracks. Such cracks are a quite well known problem that can lead to corrosion of the steel reinforcement and thus to the possible failure of the entire concrete structure. The need to repair these cracks as soon as possible leads to maintenance costs which can be of the order of â‚¬130 (direct costs) per m³ of concrete. Recent scientific studies indicate that a Microbial Induced Carbonate Precipitation (MICP), using microbial spores as active agent, can be an alternative for the actual repair methods. However, the production of bacterial spores is yet imposing considerable costs. According to some concrete producers they would be willing to pay about â‚¬15 to â‚¬20 per m³ of concrete for a bio-based self-healing product. However, the actual cost of spores production and encapsulation represent a total cost which is orders of magnitude higher. This article analyzes the costs for the biological self-healing in concrete and evaluates the industrial challenges it faces. There is an urgent need to develop the production of a bio-additive at much lower costs to make the biological self-healing industrial applicable. Axenic production and a possible non-axenic process to obtain ureolytic spores were analyzed and the costs calculations are presented in this paper.

Author Biographies

Filipe Bravo Silva, Gent University

PhD student at Gent University working in industrial environment. The main goal is to perfom an economic evaluation of the current biotechnology for self-healing concrete application and, if possible and economical feasible, up-scale the existing technology.

Nico Boon

Professor, Ghent University, Faculty of Bioscience Engineering, LabMET, Ghent, Belgium

Nele De Belie

Professor, Ghent University, Faculty of Engineering and Architecture, Department of Structural Engineering, Ghent, Belgium

Willy Verstraete

Professor, Ghent University, Faculty of Bioscience Engineering, LabMET, Ghent, Belgium

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