The investigations on properties of self-healing concrete with crystalline admixture and recycled concrete waste

Manhanga, Fallon Clare; Rudžionis, Žymantas; Ivanauskas, Ernestas; Augonis, Algirdas

doi:10.1051/matecconf/202236405002

Cited by 4 publications

(6 citation statements)

References 16 publications

(21 reference statements)

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“…When it comes to surface damage due to freeze/thaw cycles, the air-entraining agent is evidently the most effective additive for preventing damage, almost equally effective regardless of whether freezing/thawing occurs with or without salt presence, while the negative effect of the crystalline hydrophilic additive is significantly more pronounced during freezing/thawing in the presence of salt. Such research findings on the impact of the crystalline hydrophilic additive are even worse than the results presented in [51]. Specifically, Manhanga et al [51] concluded in part of their study addressing the scaling of concrete exposed to a 3% sodium chloride solution that the crystalline hydrophilic additive (in amount of 0.8% per cement weight) does not affect this type of damage caused by freeze-thaw cycles.…”

Section: Discussionmentioning

confidence: 88%

“…Such research findings on the impact of the crystalline hydrophilic additive are even worse than the results presented in [51]. Specifically, Manhanga et al [51] concluded in part of their study addressing the scaling of concrete exposed to a 3% sodium chloride solution that the crystalline hydrophilic additive (in amount of 0.8% per cement weight) does not affect this type of damage caused by freeze-thaw cycles.…”

Section: Discussionmentioning

confidence: 88%

“…Figure 10a,b confirm the conclusions regarding Figure 8a,b, namely that regarding internal damage, the air-entraining agent has shown the highest effectiveness in protecting concrete from damages caused by freeze/thaw cycles, but the crystalline hydrophilic additive at a 1% dosage (M3) has shown potential to improve concrete's resistance to freeze/thaw cycles. Furthermore, regarding internal damages, the crystalline hydrophilic additive used in this study achieved better performance in enhancing the concrete's resistance to freeze/thaw cycles compared to the crystalline hydrophilic additive used in [51]. Specifically, Manhanga et al [51] concluded, in part of their research focusing on the impact of the crystalline hydrophilic additive on the strength of cubic specimens exposed to freeze/thaw cycles in the presence of water, that the crystalline hydrophilic additive does not affect this type of damage caused by freeze-thaw cycles.…”

Section: Discussionmentioning

confidence: 89%

“…Furthermore, regarding internal damages, the crystalline hydrophilic additive used in this study achieved better performance in enhancing the concrete's resistance to freeze/thaw cycles compared to the crystalline hydrophilic additive used in [51]. Specifically, Manhanga et al [51] concluded, in part of their research focusing on the impact of the crystalline hydrophilic additive on the strength of cubic specimens exposed to freeze/thaw cycles in the presence of water, that the crystalline hydrophilic additive does not affect this type of damage caused by freeze-thaw cycles. On the other hand, Ferrara et al [55] have indeed confirmed that the velocity of the ultrasonic wave passage is higher in concrete with a crystalline hydrophilic additive compared to reference concrete during the self-healing process of cracks in concrete, leading to the conclusion that the crystalline hydrophilic additive promotes crack healing.…”

Section: Discussionmentioning

confidence: 89%

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Resistance of Concrete with Crystalline Hydrophilic Additives to Freeze–Thaw Cycles

Gojević,

Netinger Grubeša,

Juradin

et al. 2024

Applied Sciences

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The study explores the hypothesis that crystalline hydrophilic additives (CA) can enhance concrete’s resistance to freeze/thaw cycles, crucial for assessing building durability. Employing EU standards, the research evaluates concrete resistance through standardized European freeze/thaw procedures. Monitoring concrete slabs exposed to freezing in the presence of deionized water and in the presence of 3% sodium chloride solution, the study measures surface damage and relative dynamic modulus of elasticity. Additionally, it assesses internal damage through monitoring of relative dynamic modulus of elasticity on cubes and prisms submerged in water and exposed to freezing/thawing. The pore spacing factor measured here aids in predicting concrete behavior in freeze/thaw conditions. Results suggest that the standard air-entraining agent offers effective protection against surface and internal damage due to freeze/thaw cycles. However, the CA displays potential in enhancing resistance to freeze/thaw cycles, primarily in reducing internal damage at a 1% cement weight dosage. Notably, a 3% replacement of cement with CA adversely affects concrete resistance, leading to increased surface and internal damage. The findings contribute to understanding materials that can bolster concrete durability against freeze–thaw cycles, crucial for ensuring the longevity of buildings and infrastructure.

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Section: Discussionmentioning

confidence: 88%

Section: Discussionmentioning

confidence: 88%

Section: Discussionmentioning

confidence: 89%

Section: Discussionmentioning

confidence: 89%

See 2 more Smart Citations

Resistance of Concrete with Crystalline Hydrophilic Additives to Freeze–Thaw Cycles

Gojević,

Netinger Grubeša,

Juradin

et al. 2024

Applied Sciences

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“…Self-healing concreate is another widely discussed smart building material in the literature. Numerous techniques, including autogenous, chemical, and bacterial self-healing, are used in self-healing concrete to repair the material's structural integrity (Manhanga et al, 2022). Cracks and other damage on the building can be self-healed, thus enhancing the building's lifespan and reducing the need for expensive repairs (Chen et al, 2023).…”

Section: Literature Reviewmentioning

confidence: 99%

Influence of consumer motivations and perception on the adoption of smart, green, and sustainable building materials

P.,

2023

Innovative Marketing

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The purpose of this study is to analyze the barriers to the widespread use of smart, green, and sustainable building materials in the construction industry by focusing on the perceptions, motivations, strategies, and challenges faced by consumers. The analysis employed an exploratory methodology and surveyed 385 respondents in Bangalore, India. The study result shows a significant positive partial correlation (r = 0.629, p = 0.001) between the challenges of adoption and the overall factors that influence adoption after controlling the annual income as a control variable. The higher mean score of personal values and ethics of 4.25 implies that moral values and ethics influence the decisions on the adoption of construction materials. The findings of multiple regression with robust standard error revealed perception of performance of smart, green and sustainable building materials is better compared to traditional building materials (p-value = 0.001), factors positively influencing adoption (p-value = 0.004), motivating factors of adoption (p-value = 0.001) and strategies that encourage adoption of smart, green, and sustainable building materials (p-value = 0.001). All of these have a substantial influence on how consumers evaluate the government’s efforts to increase the adoption of such materials. However, challenges in adoption showed a negative coefficient (B= –0.049) and a robust standard error of 0.024 (p-value = 0.048), demonstrating a negative influence on consumers’ perception. This research acts as a guiding beacon for green adoption policies by studying consumer motivations and perceptions toward adoption of eco-friendly building materials for the sustainable future.

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Properties of Concrete Incorporated With Self-Healing and Internal Curing Agents

Rathinam,

Murali,

et al. 2023

Jurnal Teknologi

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In this study, effects of collective addition of self-healing and internal curing agents on the strength and permeation properties of concrete were determined. The internal curing agent Polyethylene Glycol (PEG 400) was added at 2% of cement based on weight and a mixture of Bentonite, Quick lime and Magnesium oxide were replaced for cement at 5% each as self-healing agent. Six mixes were investigated which includes a control mix (water curing), a mix with PEG 400 (with and without water curing), a mix with self-healing agents (water curing) and a mix integrated PEG 400 and self-healing agents. (With and without water curing) The density of concrete and strength parameters like compressive, flexural and tensile strengths were found by conducting experiments using the procedures given in testing standards. Permeation features were also studied by subjecting the concrete to water absorption and sorptivity tests. Density values lowered because of internal curing agents. The integration of internal curing and self-healing agents have adverse effects on density, strengths, water absorption and sorptivity co-efficients but there is an improvement in the mentioned properties when the specimens were cured in water.

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The investigations on properties of self-healing concrete with crystalline admixture and recycled concrete waste

Cited by 4 publications

References 16 publications

Resistance of Concrete with Crystalline Hydrophilic Additives to Freeze–Thaw Cycles

Resistance of Concrete with Crystalline Hydrophilic Additives to Freeze–Thaw Cycles

Influence of consumer motivations and perception on the adoption of smart, green, and sustainable building materials

Properties of Concrete Incorporated With Self-Healing and Internal Curing Agents

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