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Experimental Study of the Strip Coal Pillar Models Failure with Different Roof and Floor Conditions

Xiao Qu Shaojie Chen Dawei Yin Shiqi Liu
Archives of Mining Sciences | 2021 | vol. 66 | No 3 | 475-490 | DOI: 10.24425/ams.2021.138601
Keywords “roof-strip coal pillar-floor” combined specimen failure characteristics acoustic emission laboratory experiment
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Abstract

In order to study the failure mechanism and characteristics for strip coal pillars, a monitoring device for strip coal pillar uniaxial compression testing was developed. Compression tests of simulated strip coal pillars with different roof and floor rock types were conducted. Test results show that, with increasing roof and floor strength, compressive strength and elastic modulus of “roof-strip coal pillar-floor” combined specimens increase gradually. Strip coal pillar sample destruction occurs gradually from edge to the interior. First macroscopic failure occurs at the edge of the middle upper portion of the specimen, and then develops towards the corner. Energy accumulation and release cause discontinuous damage in the heterogeneous coal-mass, and the lateral displacement of strip coal pillar shows step and mutation characters. The brittleness and burst tendency of strip coal pillar under hard surrounding rocks are more obvious, stress growth rate decreases, and the rapid growth acoustic emission (AE) signal period can be regarded as a precursor for instability in the strip coal pillar. The above results have certain theoretical value for understanding the failure law and long-term stability of strip coal pillars.
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Authors and Affiliations

Xiao Qu
1
Shaojie Chen
1
Dawei Yin
Shiqi Liu
  1. Hohai University, China

Impact of acid aggressiveness on the filtration resistance of hardening slurries with an addition of fluidized-bed fly-ash

Paweł Falaciński Zbigniew Kledyński
Archives of Civil Engineering | 2021 | vol. 67 | No 2 | 475-490 | DOI: 10.24425/ace.2021.137180
Keywords hardening slurries cut-off walls acid aggressiveness fluidized-bed fly-ash circular economy
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Abstract

The subject matter of the article comprises cement-bentonite-water hardening slurries with an addition of fluidized-bed fly-ash resulting from the combustion of hard and brown coal. The main objective of the study was to determine the filtration resistance of hardening slurries in the context of long-term exposure to the filtration of an aggressive substance in relation to a cement binder. A nitric acid aqueous solution with a concentration of 0.5 M was used, which modelled acid aggressiveness. The authors studied the hydraulic conductivity of the slurries as a function of time (18 months) for the exposure to a 0.5 M solution of nitric acid. Changes in the phase composition and hardening slurry surface structures were analysed in terms of their filtration resistance to the action of acid aggressiveness. The comparative base were samples subjected to filtration in tap water (neutral environment). The article reviews a methodology for studying hydraulic conductivity (k10) of hardening slurries. It also presents a study involving the phase composition using the X-ray diffraction analysis (XRD) method, infrared (IR) spectroscopy and showing an image of the hardening slurry surface structure. The findings of other researchers that the application of fluidized-bed fly-ash additives positively impacted improving the resistance of the cement matrix to acid aggressiveness were confirmed. The hydrated colloidal compounds, identified within the subsurface zone of the slurry, which has been in contact with an acidic environment, provide extra sealing of the material structure, thus significantly limiting the access of aggressive substance to the interior of the slurry.
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Authors and Affiliations

Paweł Falaciński
1
ORCID: ORCID
Zbigniew Kledyński
2
ORCID: ORCID
  1. DSc., PhD., Eng., Warsaw University of Technology, Faculty of Building Services, Hydro and Environmental Engineering, Nowowiejska 20, 00-652 Warsaw, Poland
  2. Prof., DSc., PhD., Eng., Warsaw University of Technology, Faculty of Building Services, Hydro and Environmental Engineering, Nowowiejska 20, 00-652 Warsaw, Poland

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