Improving Payload Efficiency in Open-Pit Mining: An Integrated Model using Six Sigma and Artificial Intelligence

International Journal of Civil Engineering

© 2026 by SSRG - IJCE Journal

Volume 13 Issue 3

Year of Publication : 2026

Authors : Sebastián Alonso Paucar-La-Rosa, Jherson Luis Valencia-Vargas, Jose Antonio Rojas-Garcia, S. Nallusamy, Juan Carlos Quiroz-Flores

10.14445/23488352/IJCE-V13I3P105

How to Cite?

Sebastián Alonso Paucar-La-Rosa, Jherson Luis Valencia-Vargas, Jose Antonio Rojas-Garcia, S. Nallusamy, Juan Carlos Quiroz-Flores, "Improving Payload Efficiency in Open-Pit Mining: An Integrated Model using Six Sigma and Artificial Intelligence," SSRG International Journal of Civil Engineering, vol. 13,  no. 3, pp. 54-70, 2026. Crossref, https://doi.org/10.14445/23488352/IJCE-V13I3P105

Abstract:

Increasing the payload efficiency in open-pit mining is paramount for productivity, costs, and process variability. In this paper, an integrated methodological approach that combines Six Sigma, the PDCA cycle, and artificial intelligence is proposed to optimise the loading process in a copper mining operation. The goal is to reduce variability and increase control on the loading operation by knowing the variables that relate to the operator training, the adherence to preventive maintenance, and the monitoring of the operation. The proposed methodology was tested on an industrial case involving three truck models and used process capability indicators based on predictive analytics to assess their performance. Results indicate measurable gains in payload efficiency that range from 2.22% to 5.25% for three of the four truck models, despite the presence of a high performance level already. Availability increased from 88% to 94%, and null payloads dropped, which improved the data reliability when making decisions. Overall, the findings demonstrate that the integration of established process improvement methodologies with artificial intelsligence provides for more rigorous and repeatable control of the loading operation than the two on their own. Although mined at a single site, the proposed framework lends itself to scalability and can also be implemented in other mines. This research contributes to the advancement of data-driven process optimization in mining by providing a robust and transferable model for enhancing payload efficiency and operational performance.

Keywords:

Six Sigma, PDCA cycle, Artificial Intelligence, Payload efficiency, Open-pit mining, Process optimization.

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