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The Impact of Mining Deformations on Road Pavements Reinforced with Geosynthetics

Magdalena Zięba Piotr Kalisz Marcin Grygierek
Archives of Mining Sciences | 2020 | vol. 65 | No 4 | 751-767 | DOI: 10.24425/ams.2020.134145
Keywords road subgrade mining area horizontal strain unbound aggregate geosynthetic reinforcement laboratory test
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Abstract

In this article, the issue of mining impact on road pavements and subgrade is presented, taking into account the interaction between geosynthetic reinforcement and unbound aggregate layers. Underground mining extraction causes continuous and discontinuous deformations of the pavement subgrade. Structural deformations in the form of ruts are associated with the compaction of granular layers under cyclic loading induced by heavy vehicles. Horizontal tensile strains cause the loosening of the subgrade and base layers. The granular layers under cyclic loading are additionally compacted and the depth of ruts increases. Moreover, tensile strains can cause discontinuous deformations that affect the pavement in the form of cracks and crevices. Discontinuous deformations also affect the pavement in the fault zones during the impact of mining extraction. The use of geosynthetic reinforcement enables the mitigation of the adverse effects of horizontal tensile strains. Horizontal compressive strains can cause surface wrinkling and bumps. Subsidence causes significant changes in the longitudinal and transverse inclination of road surface. Both examples of the laboratory test results of the impact of subgrade horizontal strains on reinforced aggregate layers and the selected example of the impact of mining deformation on road subgrade are presented in this article. The examples show the beneficial impact of the use of geosynthetic reinforcement to stabilize unbound aggregate layers in mining areas.

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Authors and Affiliations

Magdalena Zięba
ORCID: ORCID
Piotr Kalisz
Marcin Grygierek

Numerical analysis of the influence of mining ground deformation on the structure of a masonry residential building

Leszek Szojda Łukasz Kapusta
Archives of Civil Engineering | 2021 | vol. 67 | No 3 | 243-257 | DOI: 10.24425/ace.2021.138054
Keywords masonry structures numerical analysis mining subsidence ground curvature ground horizontal strain
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Abstract

The article presents numerical analysis of a typical residential building in the Upper Silesian Coal Basin, which was erected in the early twentieth century and was not protected against mining ground deformations. The greatest impact of ground deformation on buildings are ground horizontal strain ε and ground curvature K. Numerical calculations included the building and the ground to take into account the effect of soilstructure interaction. The structure of the analysed building was made of masonry with wooden ceiling and roof elements. The ground was implemented as a layer 3.0m below the foundations and 3.0 m outside the building's projection. Construction loads are divided into two stages – permanent and functional loads as well as ground mining deformation. The maximum convex curvature K+ and the horizontal strain of the substrate ε+ were achieved in the 8th load step. The results of the analyses were presented in the form of stress and deformation maps. The most important results are the magnitude of the main tensile stresses σmax, which could to create cracks in the structure may occur after exceeding the tensile strength ft of the material. The presented method can be used to the analysis of endangered building objects by mining ground deformations.
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Authors and Affiliations

Leszek Szojda
1
ORCID: ORCID
Łukasz Kapusta
2
ORCID: ORCID
  1. Silesian University of Technology, Department of Structural Engineering, ul. Akademicka 5,44-100 Gliwice, Poland
  2. Kielce University of Technology, Department of Environmental, Geomatic and Energy Engineering, al. Tysiąclecia Państwa Polskiego 7, 25-314 Kielce, Poland

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