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Hybrid modelling in a digital-twin context for driveline damage detection and prevention within a mechanised, digitalising mining industry

Thesis (PhD (Mechanical Engineering))--University of Pretoria, 2026.

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Other Authors: Heyns, P.S. (Philippus Stephanus)
Format: Thesis
Language:English
Published: University of Pretoria 2026
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access_status_str Open Access
author2 Heyns, P.S. (Philippus Stephanus)
author_browse Heyns, P.S. (Philippus Stephanus)
author_facet Heyns, P.S. (Philippus Stephanus)
collection Thesis
dc_rights_str_mv © 2024 University of Pretoria. All rights reserved. The copyright in this work vests in the University of Pretoria. No part of this work may be reproduced or transmitted in any form or by any means, without the prior written permission of the University of Pretoria.
description Thesis (PhD (Mechanical Engineering))--University of Pretoria, 2026.
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institution University of Pretoria (South Africa)
language English
last_indexed 2026-07-01T04:09:21.318Z
license_str Other — see source repository
provenance_str_mv Harvested via OAI-PMH from UPSpace — University of Pretoria Institutional Repository
publishDate 2026
publishDateRange 2026
publishDateSort 2026
publisher University of Pretoria
publisherStr University of Pretoria
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source_str UPSpace — University of Pretoria Institutional Repository
spelling oai:repository.up.ac.za:2263/108496 Hybrid modelling in a digital-twin context for driveline damage detection and prevention within a mechanised, digitalising mining industry Heyns, P.S. (Philippus Stephanus) luke.vaneyk@up.ac.za van Eyk, Luke UCTD Sustainable Development Goals (SDGs) Digital twin Hybrid modelling Mechanised mining Driveline fault detection Driveline fault prevention Gearbox Skid-steered vehicle Simulation-driven domain adaptation Few-shot learning Slip prediction Traction Thesis (PhD (Mechanical Engineering))--University of Pretoria, 2026. Modern mining operations rely on large fleets of mechanised mobile equipment to ensure productivity. However, harsh duty cycles make the drivelines on these machines particularly susceptible to failure, establishing them as a primary cause of expensive, unplanned downtime. Against this backdrop, the sector is undergoing a rapid digital transformation, creating an ideal opportunity to leverage digital twins to minimise the impact of these failures. However, industry surveys conducted in this work reveal that the digital twin concept is often misunderstood, confirming the critical need for a standardised definition and approach. To address this ambiguity, this thesis first proposes a digital twin framework tailored for the mining industry. This strategic contribution defines five dimensions of a digital twin, providing a standardised structure for integrating various models to improve decision-making in mining. With this framework established, the work presents two technical contributions that address driveline damage detection and prevention. Both contributions rely on hybrid modelling methods that combine physics-based and data-driven models to provide advanced insights. The first technical contribution addresses reactive damage detection in gearboxes, specifically where historical fault data is scarce. A Simulation-Driven Domain Adaptation (SDDA) methodology was developed to overcome this “few-shot” challenge. In this approach, a generalised physics-based model generates abundant, labelled synthetic fault data, which is used to train a data-driven model. A transfer learning pipeline calibrates and adapts the data-driven model to the real gearbox data domain using limited real-world vibration signals. Validated through controlled numerical investigations and two case studies on real gearboxes, SDDA achieves high fault detection accuracy even with minimal real-world data, successfully classifying faults that purely data-driven and physics-based models fail to detect. The second technical contribution focuses on proactive damage prevention through wheel-slip prediction for skid-steered vehicles. The study finds that standard isotropic friction models are sub-optimal for modelling heavy vehicles’ behaviour on mining terrain, as they miss the directional physics of soil deformation. Consequently, an anisotropic traction model was formulated to explicitly separate the longitudinal and lateral traction coefficients. Integrated with a vehicle state estimator, this method generates real-time available torque envelopes for each wheel or track of a skid-steered vehicle. These envelopes dictate when the wheel is predicted to slip. Field experiments confirmed that this anisotropic approach captures directional traction effects significantly better than the isotropic baseline, enabling timely warnings to prevent damaging wheel slip. Ultimately, this research demonstrates the power of hybrid modelling, combining the structural interpretability of physics with the adaptive calibration of data. By framing these hybrid methods within the proposed digital twin framework, the thesis illustrates a concrete capability to transform raw sensor data into actionable insights for asset failure detection and prevention, paving the way for a more reliable, digitalised mining future. South African Mining Extraction, Research, Development and Innovation (SAMERDI) Research Activity in Mechanised Mining Systems (RAMMS) Mechanical and Aeronautical Engineering PhD (Mechanical Engineering) Unrestricted Faculty of Engineering, Built Environment and Information Technology SDG-09: Industry, innovation and infrastructure SDG-12: Responsible consumption and production 2026-02-20T07:59:53Z 2026-02-20T07:59:53Z 2026-05-18 2026-02-05 Thesis * A2026 http://hdl.handle.net/2263/108496 en © 2024 University of Pretoria. All rights reserved. The copyright in this work vests in the University of Pretoria. No part of this work may be reproduced or transmitted in any form or by any means, without the prior written permission of the University of Pretoria. application/pdf University of Pretoria
spellingShingle UCTD
Sustainable Development Goals (SDGs)
Digital twin
Hybrid modelling
Mechanised mining
Driveline fault detection
Driveline fault prevention
Gearbox
Skid-steered vehicle
Simulation-driven domain adaptation
Few-shot learning
Slip prediction
Traction
Hybrid modelling in a digital-twin context for driveline damage detection and prevention within a mechanised, digitalising mining industry
title Hybrid modelling in a digital-twin context for driveline damage detection and prevention within a mechanised, digitalising mining industry
title_full Hybrid modelling in a digital-twin context for driveline damage detection and prevention within a mechanised, digitalising mining industry
title_fullStr Hybrid modelling in a digital-twin context for driveline damage detection and prevention within a mechanised, digitalising mining industry
title_full_unstemmed Hybrid modelling in a digital-twin context for driveline damage detection and prevention within a mechanised, digitalising mining industry
title_short Hybrid modelling in a digital-twin context for driveline damage detection and prevention within a mechanised, digitalising mining industry
title_sort hybrid modelling in a digital twin context for driveline damage detection and prevention within a mechanised digitalising mining industry
topic UCTD
Sustainable Development Goals (SDGs)
Digital twin
Hybrid modelling
Mechanised mining
Driveline fault detection
Driveline fault prevention
Gearbox
Skid-steered vehicle
Simulation-driven domain adaptation
Few-shot learning
Slip prediction
Traction
url http://hdl.handle.net/2263/108496