A Research on Durability Degradation of Mineral Admixture Concrete

Chen, Xupeng; Sun, Zhuowen; Pang, Jianzhang

doi:10.3390/ma14071752

Cited by 17 publications

(9 citation statements)

References 29 publications

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“…Consequently, this process effectively mitigates the decline in later compressive strength of the concrete [ 51 ]. Li [ 52 ] and others found that the combination of RBP, slag, and fly ash can effectively improve the 28 d flexural strength of mortar; Chen [ 53 ] and others believed that the mixture of RBP and fly ash could decrease the porosity of the composite cementitious material and increase enhanced erosion resistance.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study on the Strength and Hydration Products of Cement Mortar with Hybrid Recycled Powders Based Industrial-Construction Residue Cement Stabilization of Crushed Aggregate

et al. 2023

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The strength-formation mechanism for industrial-construction residue cement stabilization of crushed aggregate (IRCSCA) is not clear. To expand the application range for recycled micro-powders in road engineering, the dosages of eco-friendly hybrid recycled powders (HRPs) with different proportions of RBP and RCP affecting the strengths of cement-fly ash mortar at different ages, and the strength-formation mechanism, were studied with X-ray diffraction (XRD) and scanning electron microscopy (SEM). The results showed that the early strength of the mortar was 2.62 times higher than that of the reference specimen when a 3/2 mass ratio of brick powder and concrete powder was mixed to form the HRP and replace some of the cement. With increasing HRP content substituted for fly ash, the strength of the cement mortar first increased and then decreased. When the HRP content was 35%, the compressive strength of the mortar was 1.56 times higher than that of the reference specimen, and the flexural strength was 1.51 times higher; XRD and SEM studies of the hydrated cement mixed with HRP showed that the amount of CH in the cement paste was reduced by the pozzolanic reaction of HRP at later hydration ages, and it was very useful in improving the compactness of the mortar. The XRD spectrum of the cement paste made with HRP indicated that the CH crystal plane orientation index R, with a diffraction angle peak of approximately 34.0, was consistent with the cement slurry strength evolution law, and this research provides a reference for the application of HRP to produce IRCSCA.

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Section: Introductionmentioning

confidence: 99%

Experimental Study on the Strength and Hydration Products of Cement Mortar with Hybrid Recycled Powders Based Industrial-Construction Residue Cement Stabilization of Crushed Aggregate

et al. 2023

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“…The expanding forces created by sulfate interacting with the calcium aluminum hydrates to form ettringite caused expansion and cracking. [8][9][10] The P-wave velocity of RuC increases as the immersion period of concrete in NaCl solution increases. RuC's mechanical characteristics improved as rubber particle size increased from 1-3 mm to 3-6 mm but decreased when rubber content increased.…”

Section: Introductionmentioning

confidence: 99%

“…Expansion, cracking, and M‐S‐H (magnesium silicate hydrate) production contributed to the reduction in compressive strength. The expanding forces created by sulfate interacting with the calcium aluminum hydrates to form ettringite caused expansion and cracking 8–10 . The P‐wave velocity of RuC increases as the immersion period of concrete in NaCl solution increases.…”

Section: Introductionmentioning

confidence: 99%

Influence of chloride and sulfate solution on the long‐term durability of modified rubberized concrete

Kumar

Verma²,

Dev

et al. 2022

J of Applied Polymer Sci

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Limited investigations are available on the influence of chloride and sulfate solutions on pozzolana‐based cement rubberized concrete after crumb rubber treatment. Mechanical and durability characteristics of rubberized concrete are assessed and compared to conventional concrete. Five contents of crumb rubber (10%–30% at 5% of increment) are utilized for partially replacing fine aggregate in concrete. The optimum amount of crumb rubber in concrete is revealed at a replacement level of 15%. The specimens remained in the crystalline form after being immersed in NaCl (sodium chloride), Na2SO4 (sodium sulfate), and MgSO4 (magnesium sulfate) solution, according to structural analyses by XRD (X‐ray diffraction). When rubberized concrete is submerged in both sulfate solutions with the same concentrations and for the same amount of time, the specimens immersed in Na2SO4 solution lose less weight and compressive strength than specimens submerged in MgSO4 solution. The losses in compressive strength of conventional concrete are 1.86%, 3.57%, and 4.82% when immersed in NaCl, Na2SO4, and MgSO4 solution. However, the losses are 1.67%, 2.79%, and 3.16% in rubberized concrete only at 24 weeks. Pozzolana‐based cement and after crumb rubber treatment, the rubberized concrete can resist chloride and sulfate solutions for a long duration.

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“…The fly ash and slag in traditional mineral admixtures have adverse effects on the mechanical performance of concrete at early stages [25]. However, because of its high pozzolanic activity, metakaolin can promote cement hydration, considerably improving the mechanical performance of concrete at the early stage [26]. Ultra-fine fly ash (UFA) is obtained by processing waste from coal-fired power plants.…”

Section: Introductionmentioning

confidence: 99%

Effect of Chlorine Salt on Durability of Mineral Admixture Concrete under Different Conditions

Chen¹,

Sun²,

Pang³

2022

Journal of Renewable Materials

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Mineral admixture concrete is a renewable material. It requires less cement than ordinary concrete and is thus beneficial for economical use of resources and environmental protection. To examine the impact of chloride salt on the durability of mineral admixture concrete under various conditions, in this study, test blocks are divided into two major groups: in one group, the test block is eroded by chloride salt on the interior and by sulphate/ magnesium salts on the exterior, and in the second group, the test block is eroded by external chloride/sulphate/ magnesium salts. Clean water is considered the control group. Dry-wet alternation tests are carried out to investigate the mechanical properties, mass, macromorphology, and ion content of the concrete. Furthermore, a series of methods, such as XRD, FT-IR, SEM, and EDS, are adopted to examine the phase composition and micromorphology of the concrete. The results show that, for the concrete subjected to the corrosion of internal chloride salt and external sulphate/magnesium salts (0-20 cycles), its mechanical properties improve slowly at the initial stage, but at the final stage (80-120 cycles), it is subjected to more severe corrosion compared to those only eroded by a single corrosive ion, such as the chloride/sulfate/magnesium salts. For concretes subjected to external corrosion of chloride/sulphate/magnesium salts, the concrete durability enhances with the concentration increase of the chloride salt. Mg 2+ and SO 4 2could jointly result in destructive damage to the admixture concrete, main generating corrosion products of ettringite, gypsum, Mg(OH) 2 , thaumasite, and M-S-H.

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A Research on Durability Degradation of Mineral Admixture Concrete

Cited by 17 publications

References 29 publications

Experimental Study on the Strength and Hydration Products of Cement Mortar with Hybrid Recycled Powders Based Industrial-Construction Residue Cement Stabilization of Crushed Aggregate

Experimental Study on the Strength and Hydration Products of Cement Mortar with Hybrid Recycled Powders Based Industrial-Construction Residue Cement Stabilization of Crushed Aggregate

Influence of chloride and sulfate solution on the long‐term durability of modified rubberized concrete

Effect of Chlorine Salt on Durability of Mineral Admixture Concrete under Different Conditions

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