Drying Shrinkage of Concrete-Causes & Mitigation
Drying shrinkage refers to the reduction in the volume of concrete as it loses moisture to the surrounding environment over time. It is a long-term phenomenon that primarily occurs due to the evaporation of water from the hardened cement paste and is a significant factor affecting the durability and performance of concrete structures.
Causes of Drying Shrinkage
2. Capillary Tension:
When water evaporates from the pores, capillary forces develop, causing tensile stresses that result in shrinkage.
3. Hydration Products:
The microstructure of hardened cement paste changes as water evaporates, leading to a reduction in volume.
Factors Affecting Drying Shrinkage
1. Concrete Composition:
2. Cement Content
3. Environmental Conditions:
4. Curing Conditions:
Inadequate curing can lead to higher shrinkage as moisture loss is unregulated.
5. Size and Shape of Concrete:
Thin or small sections experience more shrinkage due to the higher surface area-to-volume ratio.
6. Admixtures:
Chemical admixtures like shrinkage-reducing agents can lower the extent of drying shrinkage.
Consequences of Drying Shrinkage
Differential shrinkage between different parts of a structure or internal restraint can lead to cracks.
Cracking affects durability and structural integrity.
2. Reduction in Service Life:
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Cracks caused by shrinkage allow the ingress of harmful agents like water, chlorides, and carbon dioxide, leading to reinforcement corrosion.
3. Aesthetic Issues:
Visible cracks can affect the appearance of concrete structures.
Mitigation of Drying Shrinkage
2. Proper Curing:
3. Optimizing Aggregate Content:
4. Shrinkage-Reducing Admixtures:
5. Controlled Environmental Conditions:
6. Construction Joints:
7. Using Portland limestone cement (type IL) (Sharma et al., 2021)
Portland limestone cement (type IL) with replacement amounts of 10% of Portland cement has been found to give good shrinkage results without adversely affecting other engineering properties of concrete such as strength, resistivity, degree of hydration, and setting time. This is probably due to improved particle packing, access to more nucleation sites for the hydration products, and the formation of calcium carbo-aluminate hydrates. Scanning electron micrographs of coarse ground cement paste also indicated a retarded degree of hydration compared to type I/II Portland cement paste
Testing for Drying Shrinkage
Standard tests to measure drying shrinkage include:
Conclusions
Drying shrinkage is inevitable in concrete construction, but its effects can be minimized through careful mix design, proper curing, and appropriate construction practices.
Understanding and controlling drying shrinkage is critical for enhancing the durability and lifespan of concrete structures.
Reference
Chief Engineer at DWSS ( Retd )
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Energy engineer with background in electrical engineering | Green Hydrogen | Smart Buildings | Energy Efficiency | Data Science | Project Development & Management
1wIs it possible to reduce this shrinkage by using green facades?
free lance strucutural consultant at self employed
1wWhile choosing coarse aggregate size, it is preferable to choose aggregate size of 16 mm to 20 mm retained in their respective seives,with 65% of total proposes volume of coarse aggregate and we'll graded aggregate size of 10 mm to 12 mm retained in their respective sieve size for 20% and the remaining smaller size for 15%. This proportion of well graded coarse aggregate with fine aggregate having finness modulus of 3, reduces the bonding surface area with less cement content and water cement ratio of 0.45 gives a good compaction factor of 0.95 and reduces shrinkage cracks. Besides, the water curing after 6 hours of pouring concrete by water sprinklers compensate the evaporated water to effectively continue it's hydration process leading to a dense durable concrete with relatively higher strength.
L. K. JAIN Associates, Consuting Group
1wIt may be added that, there is a time delay involved in loss of moisture from concrete and the shrinkage taking place.