Your search keyword '"Alison McQuillan"' showing total 14 results

1. The development and implementation of design flowchart for probabilistic rock slope stability assessments: a review

Author

Ibnu Rusydy, Ismet Canbulat, Chengguo Zhang, Chunchen Wei, and Alison McQuillan

Subjects

Probabilistic, Rock slope, Slope stability, Probability of failure, Disasters and engineering, TA495, Environmental sciences, GE1-350

Abstract

Abstract Background Rock slope instability is a complex geotechnical issue that is affected by site-specific rock properties, geological structures, groundwater, and earthquake load conditions. Numerous studies acknowledge these aleatory uncertainties in slope stability assessment; however, understanding the rock behaviour could still be improved. Therefore, this paper aims to summarise the probability methods applied in rock slope stability analysis in mining and civil engineering and develop new probabilistic design and assessment methodologies for four methods, namely empirical/rock mass classifications techniques, kinematic analysis, limit equilibrium (LE), and numerical methods and introduces how to integrate all methods to determine the total probability of failure. The case studies have been conducted based on slopes from Indonesia, a seismically active country, utilising the proposed design methods. Results Regarding the probabilistic empirical/rock mass classification (RMC) technique, this study has identified that seven of the ten most involved input parameters in RMC naturally exhibit aleatory uncertainty. Thus, the optimal way to present the output probability of RMC is as a confidence interval (CI) or total and conditional probability associated with each rock mass class. In probabilistic kinematic analysis, this study presents a systematic method to compute the probabilities of different types of failure alongside the total probability of occurrence (P tK ). The probability of failure (PoF) for jointed generalized Hoek-Brown (GHB) numerical modelling was lower than that obtained through the probabilistic LE approach for a similar slope. However, the PoF of jointed GHB is higher than the LE approach when loaded with 0.1 and 0.15 earthquake coefficients. Conclusions The variation of PoF across different failure criteria determines how epistemic uncertainty is apparent in the modelling process, while the aleatory uncertainty arises from input parameters. Furthermore, this study introduces the total probability of failure equation as a combination of kinematic and kinetic probabilities (limit equilibrium and numerical modelling).

Published

2024

2. A Comparative Study of Embedded Wall Displacements Using Small-Strain Hardening Soil Model

Author

Tzuri Eilat, Amichai Mitelman, Alison McQuillan, and Davide Elmo

Subjects

embedded walls, earth-retaining walls, hardening soil model, geotechnical analysis, numerical modeling, machine learning, Dynamic and structural geology, QE500-639.5

Abstract

Traditional analysis of embedded earth-retaining walls relies on simplistic lateral earth pressure theory methods, which do not allow for direct computation of wall displacements. Contemporary numerical models rely on the Mohr–Coulomb model, which generally falls short of accurate wall displacement prediction. The advanced constitutive small-strain hardening soil model (SS-HSM), effectively captures complex nonlinear soil behavior. However, its application is currently limited, as SS-HSM requires multiple input parameters, rendering numerical modeling a challenging and time-consuming task. This study presents an extensive numerical investigation, where wall displacements from numerical models are compared to empirical findings from a large and reliable database. A novel automated computational scheme is created for model generation and advanced data analysis is undertaken for this objective. The main findings indicate that the SS-HSM can provide realistic predictions of wall displacements. Ultimately, a range of input parameters for the utilization of SS-HSM in earth-retaining wall analysis is established, providing a good starting point for engineers and researchers seeking to model more complex scenarios of embedded walls with the SS-HSM.

Published

2024

3. Back-Analysis of Structurally Controlled Failure in an Open-Pit Mine with Machine Learning Tools

Author

Alison McQuillan, Amichai Mitelman, and Davide Elmo

Subjects

slope stability, open-pit mine, machine learning, back-analysis, numerical modelling, kinematic failure, Dynamic and structural geology, QE500-639.5

Abstract

Over the past decades, numerical modelling has become a powerful tool for rock mechanics applications. However, the accurate estimation of rock mass input parameters remains a significant challenge. Machine learning (ML) tools have recently been integrated to enhance and accelerate numerical modelling processes. In this paper, we demonstrate the novel use of ML tools for calibrating a state-of-the-art three-dimensional (3D) finite-element (FE) model of a kinematic structurally controlled failure event in an open-pit mine. The failure event involves the detachment of a large wedge, thus allowing for the accurate identification of the geometry of the rock joints. FE models are automatically generated according to estimated ranges of joint input parameters. Subsequently, ML tools are used to analyze the synthetic data and calibrate the strength parameters of the rock joints. Our findings reveal that a relatively small number of models are needed for this purpose, rendering ML a highly useful tool even for computationally demanding FE models.

Published

2023

4. Rapid and robust slope failure appraisal using aerial photogrammetry and 3D slope stability models

Author

Neil Bar, Michael Kostadinovski, Michael Tucker, Glen Byng, Rully Rachmatullah, Arturo Maldonado, Markus Pötsch, Andreas Gaich, Alison McQuillan, and Thamer Yacoub

Subjects

Slope stability, 3D limit equilibrium analysis, Aerial imagery, Photogrammetry, Open pit mining, Mining engineering. Metallurgy, TN1-997

Abstract

Slope failures are an inevitable aspect of economic pit slope designs in the mining industry. Large open pit guidelines and industry standards accept up to 30% of benches in open pits to collapse provided that they are controlled and that no personnel are at risk. Rigorous ground control measures including real time monitoring systems at TARP (trigger-action-response-plan) protocols are widely utilized to prevent personnel from being exposed to slope failure risks. Technology and computing capability are rapidly evolving. Aerial photogrammetry techniques using UAV (unmanned aerial vehicle) enable geotechnical engineers and engineering geologists to work faster and more safely by removing themselves from potential line-of-fire near unstable slopes. Slope stability modelling software using limit equilibrium (LE) and finite element (FE) methods in three dimensions (3D) is also becoming more accessible, user-friendly and faster to operate. These key components enable geotechnical engineers to undertake site investigations, develop geotechnical models and assess slope stability faster and in more detail with less exposure to fall of ground hazards in the field. This paper describes the rapid and robust process utilized at BHP Limited for appraising a slope failure at an iron ore mine site in the Pilbara region of Western Australia using a combination of UAV photogrammetry and 3D slope stability models in less than a shift (i.e. less than 12 h).

Published

2020

5. Methods applied in Australian industry to evaluate coal mine slope stability

Author

Alison McQuillan, Ismet Canbulat, and Joung Oh

Subjects

Mining engineering. Metallurgy, TN1-997

Abstract

Strata failure is a principal hazard in open cut coal mining as it has the potential to cause multiple fatalities. Prior to the excavation of any slope, a geotechnical assessment should review the likely slope performance, including the risk of slope failure. Controls to manage this risk to an acceptable level should accompany the geotechnical analysis. A survey of 43 practising geotechnical engineers indicated that kinematic and 2D limit equilibrium analyses were the methods most commonly applied to analyse excavated slope stability. While these methods are well established and widely applied in the broad rock engineering disciplines (e.g. civil, hard rock), a recent review of over 60 slope failures suggests these methods have limited suitability for modelling the complex failure mechanisms observed in excavated coal mine slopes. Kinematic techniques do not adequately capture the rock mass component of excavated slope failure and do not provide a geospatial location of potential failure, while 2D limit equilibrium techniques do not adequately capture the 3D mechanisms of excavated slope failures. Methods which do consider the 3D mechanisms of slope failure are summarized for industry consideration and application. Keywords: Slope stability, 2D, 3D, Open cut coal mine, Limit equilibrium

Published

2020

6. Q-slope and SSAM applied to excavated coal mine slopes

Author

Neil Bar and Alison McQuillan

Subjects

Slope stability, Q-slope, Open cut coal, Science

Abstract

The Q-slope classification system is used to assess the stability of excavated rock slopes and provide an indication of long-term stable, reinforcement-free slope angles. Q-slope is based on over 500 rock slope case studies from mines, road and rail cuttings hosted in igneous, sedimentary and metamorphic rocks around the world. Q-slope can be applied for slopes ranging from less than 5 m to more than 250 m in height in both civil and mining environments.This paper describes the application of Q-slope classification system to 38 failed and intact slopes from Australian open cut coal mines. It further describes the relationship between Q-slope and Slope Stability Assessment Methodology (SSAM) ratings for stable slopes based on the available case studies.

Published

2021

7. Corrigendum to 'Q-slope and SSAM applied to excavated coal mine slopes' [MethodsX 8 (2021) 101191]

Author

Neil Bar and Alison McQuillan

Subjects

Science

Published

2021

8. New risk assessment methodology for coal mine excavated slopes

Author

Alison McQuillan, Ismet Canbulat, Dan Payne, and Joung Oh

Subjects

Mining engineering. Metallurgy, TN1-997

Abstract

This paper presents a new risk assessment methodology for coal mine excavated slopes. This new empirical-statistical slope stability assessment methodology (SSAM) is intended for use by geotechnical engineers at both the design review and operational stages of a mine’s life to categorise the risk of an excavated coal mine slope. A likelihood of failure is determined using a new slope stability classification system for excavated coal mine slopes developed using a database of 119 intact and failed case studies sourced from open cut coal mines in Australia. Consequence of failure is based on slope height and stand-off distance at the toe of the excavated slope. Results are presented in a new risk matrix, with slope risk being divided into low, medium and high categories. The SSAM is put forward as a new risk assessment methodology to assess the potential for, and consequence of, excavated coal mine slope failure. Unlike existing classification systems, assumptions about the likely failure mode or mechanism are not required. Instead, the SSAM applies an approach which compares the conditions present within the excavated slope face, with the known past performance of slopes with similar geotechnical and geometrical conditions, to estimate the slope’s propensity for failure. The SSAM is novel in that it considers the depositional history of strata in an excavated slope and how this sequence affects slope stability. It is further novel in that it does not require explicit measurements of intact rock, rock mass and/or defect strength to rapidly calculate a slope’s likelihood of failure and overall risk. Ratings can be determined entirely from visual observations of the excavated slope face. The new SSAM is designed to be used in conjunction with existing slope stability assessment tools. Keywords: Risk assessment, Slope stability, Open cut coal mine, Excavated slope, Likelihood of failure

Published

2018

9. Rapid and robust slope failure appraisal using aerial photogrammetry and 3D slope stability models

Author

Glen Byng, Neil Bar, Michael Kostadinovski, Markus Pötsch, Arturo Maldonado, Alison McQuillan, Andreas Gaich, Rully Rachmatullah, Michael Tucker, and Thamer Yacoub

Subjects

lcsh:TN1-997, Process (engineering), Slope stability, Energy Engineering and Power Technology, Monitoring system, Open pit mining, Geotechnical Engineering and Engineering Geology, Mine site, 3D limit equilibrium analysis, Slope failure, Mining industry, Photogrammetry, Mining engineering, Geochemistry and Petrology, Aerial imagery, lcsh:Mining engineering. Metallurgy, Geology, Modelling software

Abstract

Slope failures are an inevitable aspect of economic pit slope designs in the mining industry. Large open pit guidelines and industry standards accept up to 30% of benches in open pits to collapse provided that they are controlled and that no personnel are at risk. Rigorous ground control measures including real time monitoring systems at TARP (trigger-action-response-plan) protocols are widely utilized to prevent personnel from being exposed to slope failure risks. Technology and computing capability are rapidly evolving. Aerial photogrammetry techniques using UAV (unmanned aerial vehicle) enable geotechnical engineers and engineering geologists to work faster and more safely by removing themselves from potential line-of-fire near unstable slopes. Slope stability modelling software using limit equilibrium (LE) and finite element (FE) methods in three dimensions (3D) is also becoming more accessible, user-friendly and faster to operate. These key components enable geotechnical engineers to undertake site investigations, develop geotechnical models and assess slope stability faster and in more detail with less exposure to fall of ground hazards in the field. This paper describes the rapid and robust process utilized at BHP Limited for appraising a slope failure at an iron ore mine site in the Pilbara region of Western Australia using a combination of UAV photogrammetry and 3D slope stability models in less than a shift (i.e. less than 12 h).

Published

2020

10. The Evolution of Geotech - 25 Years of Innovation

Author

Thamer Yacoub, J.H. Curran, Reginald Hammah, and Alison McQuillan

Subjects

Earthquake engineering, Engineering, business.industry, Forensic engineering, business

Published

2021

11. Corrigendum to 'Q-slope and SSAM applied to excavated coal mine slopes' [MethodsX 8 (2021) 101191]

Author

Alison McQuillan and Neil Bar

Subjects

Medical Laboratory Technology, Mining engineering, business.industry, Science, Clinical Biochemistry, Coal mining, business, Geology

Published

2021

12. Three-dimensional slope stability modelling and its interoperability with interferometric radar data to improve geotechnical design

Author

Sinaka Rea, Thamer Yacoub, Neil Bar, Alison McQuillan, Niccolò Coli, Lorenzo Leoni, and James Bu

Subjects

Synthetic aperture radar, law, Section (archaeology), Computer science, Slope stability, Interoperability, Geotechnical engineering, Limit (mathematics), Radar, Material properties, Finite element method, law.invention

Abstract

Commercial 3D limit equilibrium and 3D finite element analysis software has been available to geotechnical engineers for nearly a decade. Current 3D modelling software allows the direct importation of as-built designs to back-analyse slope stability. The same 3D modelling software allows the direct importation of deformation data recorded by slope stability radars. This interoperability between modelling software and monitoring data provides geotechnical engineers an invaluable method to back-analyse material properties and refine slope stability models. This paper presents a case study showing the integration of 3D limit equilibrium, 3D finite element and synthetic aperture radar monitoring data to determine suitable remediation actions to stabilise an identified deforming section of slope in an open cut gold mine.

Published

2020

13. The Evolution of Geotech - 25 Years of Innovation

Author

Reginald Hammah, Thamer Yacoub, Alison McQuillan, John Curran, Reginald Hammah, Thamer Yacoub, Alison McQuillan, and John Curran

Subjects

Geotechnical engineering--Congresses

Abstract

This publication includes 82 technical papers presented at Rocscience International Conference (RIC) 2021, held online on April 20 and 21, 2021. Rocscience created this event to bring geotechnical academics, researchers and practitioners together to exchange ideas as part of celebrating 25 years of the company's existence.The papers in these proceedings were from keynotes, panel discussions and papers, selected after careful review of over 100 technical submissions delivered at RIC 2021. The technical papers were grouped into sessions based on their subject areas.The conference aimed to stimulate discussions that could help the industry work towards overcoming geotechnical engineering limitations today. It also sought to foster creative thinking that will advance the current states of the art and practice. The keynote addresses, panel discussions and technical presentations tried to examine geotechnical problems and situations from fresh perspectives. RIC 2021 hopes that the proceedings will continue to enrich our thinking and contribute to achieving a critical mass of change in our practices and approaches. We look forward to significant improvements in our industry.

Published

2021

14. Loz The Worry-Eating Monster

Author

Alison McQuillan and Alison McQuillan

Abstract

Loz loved to eat worries. Loz was a worry-eating monster.Loz loved to eat worries - little worries, big worries, worries about food, worries about school, worries about absolutely anything.Sitting in his special chair, Loz would wait for the sound of tinkling silver bells and then be off to eat a child's worries. It was the best job in the world.

Published

2019