Concrete Repair Durability
Abstract
:1. Introduction
- Overall, in construction, the linkage between theory and practice is of great importance.
- In the field of repair, it may happen at any moment that practice triumphs over modern theory. It is sufficient to say that concrete repair has been performed since the introduction of concrete into construction practice (Eddystone lighthouse, 1756), but the standard for concrete repair was established in USA through the ACI-1999 Concrete Repair Manual, and in Europe in 2004–2013 according to the volumes of European Standards EN 1504.1-10.
2. Question about Repair Durability
3. Repair as a Strategy of Managing Structure Durability
- the use potential is always restored back to the original condition
- the destruction rate does not change as a result of the repair
- the fact that the repair occurs in time is not taken into account (the repair arrows are oriented upwards)
4. Repair Durability Determinants
- adhesion—high; it is the prerequisite for successful repair: the higher the adhesion, the higher the tolerances for any potential compatibility errors [43]
- shrinkage—low; excessive shrinkage [44] is often the cause of unsuccessful repairs
- tensile strength—high
- fatigue strength—high [19]
- chloride penetration—low
- susceptibility to carbonation—low
- resistance to aggressive environmental impact—high
- Young’s modulus,
- creep factor,
- coefficient of thermal expansion,
- water absorbability.
5. Estimating Repair Durability
6. Conclusions
- A successful repair means that there are “no cracks” occurring throughout the estimated service life. This means that the adhesion, fA in the repair joints should be above tensile strength of the concrete, ftC and internal shrinkage stress, σt. Therefore, we arrive at: fA ≥ ftR ≥ ftC ≥ σt that should be maintained throughout the expected service life.
- The adhesion between repair materials and concrete structures is a decisive factor of radical concrete repairs. The answer to ensuring a high level of adhesion is the presence of the polymer in repair materials. This means that if a repaired concrete is of a higher class, we would need a repair material with a higher polymer content.
- Concrete repairing impact on the repair durability is acting according to the two mechanisms:
- -
- Restore the original (or even improved) application potential,
and/or- -
- The reduction of the rate of destruction process.
- The distribution function of the aforementioned repaired structural damages indicates that the durability of 50% of these repairs is less than 10 years. These poor results relate to historical structures and past attempts at repairing them. The expected repair durability median value is 25 years. Successful repairs are not only dependent on observing best practices in a given period, but also on the skills of people executing the repairs. There is an opportunity to manage repair strategy in a proactive way to assure expected durability of repaired concrete.
Author Contributions
Funding
Conflicts of Interest
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Czarnecki, L.; Geryło, R.; Kuczyński, K. Concrete Repair Durability. Materials 2020, 13, 4535. https://doi.org/10.3390/ma13204535
Czarnecki L, Geryło R, Kuczyński K. Concrete Repair Durability. Materials. 2020; 13(20):4535. https://doi.org/10.3390/ma13204535
Chicago/Turabian StyleCzarnecki, Lech, Robert Geryło, and Krzysztof Kuczyński. 2020. "Concrete Repair Durability" Materials 13, no. 20: 4535. https://doi.org/10.3390/ma13204535
APA StyleCzarnecki, L., Geryło, R., & Kuczyński, K. (2020). Concrete Repair Durability. Materials, 13(20), 4535. https://doi.org/10.3390/ma13204535