The Effect of Exposure on the Autogenous Self-Healing of Ordinary Portland Cement Mortars

Rajczakowska, Magdalena; Habermehl-Cwirzen, Karin; Hedlund, Hans; Ćwirzeń, Andrzej

doi:10.3390/ma12233926

Cited by 16 publications

(13 citation statements)

References 47 publications

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“…However, due to a high amount of unhydrated cement and limestone particles, the material has self-healing potential, which could be further improved by the application of a more efficient curing regime. Recent results have shown that curing of cracked concrete with a mixture of water and retarding admixture can lead to a successful self-healing [ 73 ].…”

Section: Resultsmentioning

confidence: 99%

Eco-UHPC as Repair Material—Bond Strength, Interfacial Transition Zone and Effects of Formwork Type

et al. 2020

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A reduced carbon footprint and longer service life of structures are major aspects of circular economy with respect to civil engineering. The aim of the research was to evaluate the interfacial bond properties between a deteriorated normal strength concrete structure and a thin overlay made of Eco-UHPC containing 50 wt% of limestone filler. Two types of formwork were used: untreated rough plywood and surface treated shuttering plywood. The normal strength concrete elements were surface scaled using water jets to obtain some degradation prior to casting of the UHPC overlay. Ultrasonic pulse velocity (UPV), bond test (pull-off test), and Scanning Electron Microscopy (SEM) combined with Energy Dispersive Spectrometry (EDS) were used for analysis. Elements repaired with the Eco-UHPC showed significantly improved mechanical properties compared to the non-deteriorated NSC sample which was used as a reference. The bond strength varied between 2 and 2.7 MPa regardless of the used formwork. The interfacial transition zone was very narrow with only slightly increased porosity. The untreated plywood, having a rough and water-absorbing surface, created a surface friction-based restraint which limited microcracking due to autogenous shrinkage. Shuttering plywood with a smooth surface enabled the development of higher tensile stress on the UHPC surface, which led to a more intensive autogenous shrinkage cracking. None of the formed microcracks penetrated through the entire thickness of the overlay and some were partly self-healed when a simple water treatment was applied. The project results showed that application of UHPC as repair material for concrete structures could elongate the lifespan and thus enhance the sustainability.

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Section: Resultsmentioning

confidence: 99%

Eco-UHPC as Repair Material—Bond Strength, Interfacial Transition Zone and Effects of Formwork Type

et al. 2020

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“…• The exposure used to activate the recovery process was limited to water cycles. Recent results [9] showed that applying different solutions as healing activators, e.g. lime water or a mixture of water with retarding admixture can increase the efficiency of the selfhealing process; • Due to possible agglomeration issues [36], the amount of nanomaterials applied in this experiment was relatively small, i.e.…”

Section: Conclusion and Future Researchmentioning

confidence: 99%

“…Ordinary concrete has an in-built ability to repair its damage for cracks up to 150 µm when exposed to water, called autogenous self-healing [6]. The efficiency of the autogenous self-healing can be improved with "boosting" ingredients, e.g., the addition of certain types of fibres [7,8] or specific exposure conditions [9]. The properties of high-temperature damaged concrete can also be partially "healed" by exposing it to post-fire curing.…”

Section: Introductionmentioning

confidence: 99%

Is Cement Paste Modified with Carbon Nanomaterials Capable of Self-Repair after a Fire?

Rajczakowska

Szeląg

Habermehl-Cwirzen

et al. 2022

Nordic Concrete Research

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This manuscript presents preliminary results on the cement paste potential, with and without carbon nanomaterials, to heal high-temperature cracks. Cement paste beams were subjected to thermal loading of 200°C and 400°C after 28 days of water curing. High temperature caused the formation of microcrack networks on the specimen’s surface. Self-healing was achieved by exposing the cracked samples to cyclic water immersion. The efficiency of the process was evaluated based on the crack closure and mechanical properties recovery after 24 days. The results indicated a distinct dependence of the healing on the loading temperature. Carbon nanotubes had a positive effect on self-repair efficiency.

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“…In that specific case, cracks of size 0.458 mm were completely closed by autogenous self-healing in 30 days by the production of calcium carbonate (CaCO 3 ). Another study analyzed concrete healing in water containing micro silica particles [13] and detected precipitates of calcium silicate hydrate and calcium carbonate in the interior of the crack, improving the crack healing efficiency.…”

Section: Introductionmentioning

confidence: 99%

Concrete Early-Age Crack Closing by Autogenous Healing

Roig-Flores

Ros

2020

Sustainability

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Autogenous healing is mainly produced by continuing hydration or carbonation. The aim of this research is to quantify the crack closing produced by autogenous healing for early-age concrete. This healing was evaluated for two crack size levels, 0.1 mm and 0.4 mm, under three healing conditions: water immersion, a humidity chamber, and wet/dry cycles. Crack closing was evaluated after 7, 14, 28 and 42 days under healing conditions. The internal status of the cracks was verified visually and using phenolphthalein. The results show that specimens stored in the humidity chamber did not experience healing, while specimens under wet/dry cycles and water immersion achieved the complete closing of small-sized cracks (under 0.15 mm). Autogenous healing showed higher speed under wet/dry cycles but higher final efficiency under water immersion. However, the inspection of the interior of the specimens showed that self-closing occurred mostly on the surface, and carbonation in the crack faces was only noticed very near the specimen’s surface. Additionally, this study proposes a preliminary strategy to model autogenous healing in concrete in terms of crack closing.

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The Effect of Exposure on the Autogenous Self-Healing of Ordinary Portland Cement Mortars

Cited by 16 publications

References 47 publications

Eco-UHPC as Repair Material—Bond Strength, Interfacial Transition Zone and Effects of Formwork Type

Eco-UHPC as Repair Material—Bond Strength, Interfacial Transition Zone and Effects of Formwork Type

Is Cement Paste Modified with Carbon Nanomaterials Capable of Self-Repair after a Fire?

Concrete Early-Age Crack Closing by Autogenous Healing

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