A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Novel nanomagnetic-based slurry for grouting fractured rocks
In geo-engineering and underground infrastructure projects, flaws and discontinuities in rocks are typically grouted to enhance hydraulic properties, reduce permeability, and mitigate hazards. Traditional grouts, however, often exhibit poor dispersion resistance and bonding properties, highlighting the need for alternative grouting technologies for fractured rocks. Moreover, the mechanisms by which grout materials seal fractured rocks and respond to in-situ compressional stresses remain inadequately understood. This study proposes a novel nanomagnetic-based grout, characterized by its natural expansiveness, which can induce compressive stress and potentially enhance rock fracture grouting, in addition to evaluating the efficacy of this nanomagnetic slurry as a grout for rock masses, and its ability to modify bulk rock strength (uniaxial compressive strength, UCS; Young’s modulus, E). Mechanical properties of the rock samples were obtained via uniaxial compression tests conducted before and after grouting treatment. Microstructural analysis and material uniformity were assessed using Scanning Electron Microscopy (SEM). Additionally, changes in rock density before and after grouting were analyzed via grout flow performance to understand its flowability. The results indicate that the proposed nanomagnetic grout can significantly improve the UCS of treated samples and effectively plug fractured rocks. The optimal grout treatment, containing 15% nanomagnetic material content, resulted in greater bulk UCS by up to 42%, E by up to 31%, and bulk rock density. Further analyses suggest that the nanomagnetic grout can alter rock microstructure and ensure good material uniformity with efficient flow rates. This work provides new insights into the development of eco-friendly reinforcement and void-filling materials for mitigating geohazards around high-risk and challenging underground infrastructures by using nanomaterials, advancing rock engineering applications, and enhancing the understanding of rock grouting from a rock mechanics perspective.
Novel nanomagnetic-based slurry for grouting fractured rocks
In geo-engineering and underground infrastructure projects, flaws and discontinuities in rocks are typically grouted to enhance hydraulic properties, reduce permeability, and mitigate hazards. Traditional grouts, however, often exhibit poor dispersion resistance and bonding properties, highlighting the need for alternative grouting technologies for fractured rocks. Moreover, the mechanisms by which grout materials seal fractured rocks and respond to in-situ compressional stresses remain inadequately understood. This study proposes a novel nanomagnetic-based grout, characterized by its natural expansiveness, which can induce compressive stress and potentially enhance rock fracture grouting, in addition to evaluating the efficacy of this nanomagnetic slurry as a grout for rock masses, and its ability to modify bulk rock strength (uniaxial compressive strength, UCS; Young’s modulus, E). Mechanical properties of the rock samples were obtained via uniaxial compression tests conducted before and after grouting treatment. Microstructural analysis and material uniformity were assessed using Scanning Electron Microscopy (SEM). Additionally, changes in rock density before and after grouting were analyzed via grout flow performance to understand its flowability. The results indicate that the proposed nanomagnetic grout can significantly improve the UCS of treated samples and effectively plug fractured rocks. The optimal grout treatment, containing 15% nanomagnetic material content, resulted in greater bulk UCS by up to 42%, E by up to 31%, and bulk rock density. Further analyses suggest that the nanomagnetic grout can alter rock microstructure and ensure good material uniformity with efficient flow rates. This work provides new insights into the development of eco-friendly reinforcement and void-filling materials for mitigating geohazards around high-risk and challenging underground infrastructures by using nanomaterials, advancing rock engineering applications, and enhancing the understanding of rock grouting from a rock mechanics perspective.
Novel nanomagnetic-based slurry for grouting fractured rocks
Discov Civ Eng
Oppong, Felix (author) / Kolawole, Oladoyin (author)
2025-01-07
Article (Journal)
Electronic Resource
English
| European Patent Office | 2024
Novel grouting slurry for mining regenerated roof and preparation method of novel grouting slurry
| European Patent Office | 2023