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Corrosion of Reinforcement01:27

Corrosion of Reinforcement

300
The corrosion of steel reinforcement within concrete is a process influenced by the material's inherent properties and external factors. The high pH level of around 13, provided by calcium hydroxide present in concrete, initially protects the steel reinforcement by promoting the formation of a passive iron oxide layer on its surface.
However, over time and under certain conditions like carbonation, chloride ingress, and cracking this protective state can be compromised. Steel has areas with...
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Waterproofing and Anti-Bacterial Admixtures in Concrete01:22

Waterproofing and Anti-Bacterial Admixtures in Concrete

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Concrete's susceptibility to water absorption is due to the capillary action within the pores of its hydrated cement paste. This action draws water in, creating the need for waterproofing admixtures to prevent such penetration. The efficacy of these admixtures is contingent upon the water pressure, with variations arising from different conditions such as rain, capillary rise, or hydrostatic pressure in structures intended to hold water.
Waterproofing admixtures render concrete hydrophobic,...
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Testing Water Quality01:14

Testing Water Quality

212
When the quality of water for concrete preparation is uncertain, its impact on the setting time of cement and compressive strength of mortar is assessed by comparison with de-ionized or distilled water benchmarks. American Society for Testing and Materials (ASTM) C1602 requires the setting times to be within 90 minutes of the control, British Standard (BS) 3146:1980 allows a 30-minute variance in the initial setting, while British Standards European Norm (BS EN) 1008 specifies initial setting...
212
Curing of Concrete01:20

Curing of Concrete

203
The hydration of cement takes place within the water-filled capillary pores. However, environmental elements can disrupt this process by evaporating water from the concrete surfaces. Sealed concrete with a water-cement ratio below 0.5 experiences self-desiccation, leading to water loss. The water loss in concrete is mitigated by curing. This technique involves keeping the concrete saturated to maintain the necessary temperature and moisture conditions, to optimally fill the spaces in the cement...
203
Non-destructive Tests for Concrete Strength01:12

Non-destructive Tests for Concrete Strength

228
The rebound hammer test, also known as the Schmidt hammer test, is a non-destructive technique for evaluating the hardness of concrete and, indirectly, the strength of concrete. It operates on the principle that the rebound of a spring-driven mass from a concrete surface correlates to the surface's hardness. The device comprises a mass within a tubular housing, a spring mechanism, and a plunger that strikes the concrete. Upon release, the energy imparted to the mass by the spring causes it...
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Permeability of Concrete01:25

Permeability of Concrete

258
Permeability in the context of concrete refers to how easily liquids or gases can pass through the material. This quality is crucial for assessing the water-tightness and durability of concrete structures and their resistance to chemical attacks. Concrete permeability can be determined through comparative laboratory tests. These tests typically involve sealing a concrete specimen from the sides, applying water pressure to the top surface with pressure, and measuring the amount of water passing...
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Related Experiment Video

Updated: Oct 18, 2025

Applicability Analysis of Assessment Methods for Morphological Parameters of Corroded Steel Bars
10:24

Applicability Analysis of Assessment Methods for Morphological Parameters of Corroded Steel Bars

Published on: November 1, 2018

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Service Life Evaluation for RC Sewer Structure Repaired with Bacteria Mixed Coating: Through Probabilistic and

Hyun-Sub Yoon1, Keun-Hyeok Yang1, Kwang-Myong Lee2

  • 1Department of Architectural Engineering, Kyonggi University, Suwon 16227, Korea.

Materials (Basel, Switzerland)
|September 28, 2021
PubMed
Summary
This summary is machine-generated.

This study developed a bacteria-coating for reinforced concrete (RC) structures to enhance durability in sulfate environments. The bacteria-coating significantly extends service life compared to traditional repair methods.

Keywords:
Rhodobacter capsulatuscover depthservice lifesewage concretesulfate ionsurface coating

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Area of Science:

  • Civil Engineering
  • Materials Science
  • Environmental Engineering

Background:

  • Sulfate exposure causes concrete swelling and cracking, reducing the service life of structures.
  • Engineering modeling is crucial for evaluating the service life of concrete structures in sulfate environments.

Purpose of the Study:

  • To develop and evaluate cementitious repair materials with bacteria (Rhodobacter capsulatus) for enhanced concrete durability.
  • To assess the service life of reinforced concrete (RC) structures using a novel bacteria-coating through deterministic and probabilistic methods.

Main Methods:

  • Developed cementitious repair materials incorporating Rhodobacter capsulatus and porous spores for immobilization.
  • Evaluated service life using deterministic and probabilistic methods, considering parameters like coating thickness, diffusion coefficient, surface roughness, and sulfate ion concentration.
  • Analyzed the impact of varying mean and coefficient of variation (COV) of design parameters on service life.

Main Results:

  • Probabilistic methods yielded more conservative service life estimates than deterministic methods.
  • Coating thickness and surface roughness were identified as critical design parameters for ensuring service life.
  • In a 200 ppm sulfate environment, the bacteria-coating extended service life by 1.47-1.50 times compared to normal repair mortar.
  • The bacteria-coating's effectiveness was significantly enhanced with a low COV (around 0.1).

Conclusions:

  • The developed bacteria-coating is a highly effective method for extending the service life of RC structures in sulfate-rich environments.
  • The probabilistic approach provides a more realistic assessment of service life under varying conditions.
  • Optimizing coating thickness and surface roughness is key to maximizing the benefits of bacteria-coating for concrete durability.