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T.G.A. Meijer
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The goal of a mining operation is to extract the maximum value from exploiting the orebody. The equipment used by these mining operations has a nominally rated performance to achieve needed annual production. However, this nominally rated performance is not achieved during operations. This study assesses the underlying causes of reduced shovel production in a mining operation.
The following research questions will be answered in this study: What factors contribute to deviations from the predicted performance? What factors are the most significant? What is the effect of automated trucks on shovel productivity? Can a data-driven model be developed to predict the actual productivity of the shovel in the real world?
The underlying causes of reduced shovel production are assessed through a literature review and five case studies. The case studies consisted of three data analytical desk studies, interviews with industry professionals, and a mine visit to north Africa.
The literature review shows that the mining industry uses formulas to determine the theoretical production rates. The factors in the shovel production formula should be predicted with frequency distributions. Also, truck automation will increase trucking hours, impacting shovel productivity through truck exchange time. The first case study shows a sensitivity analysis of the shovel formula. This sensitivity analysis shows that the swell factor, density, bucket fill, efficiency, and cycle time have a more significant impact than truck exchange time, dumping of the first bucket, and the number of cycles. The second case study shows the underperformance of different electric rope shovel models in different mining operations. The third case study compares the theoretical shovel capacity with the total material moved for 16 years. This shovel capacity and total material ratio should be between 1-2.5 for a mining operation to be classified as above-average-in-class. The fourth case study shows the different factors influencing shovel productivity based on the interviewees' responses. The last case study shows the effects of operational decisions on a mining operation. The literature review and case studies are used to develop a flowchart regarding the factors influencing shovel productivity.
This flowchart was used to synthesise the results. The difference between theoretical and real-world production rates can be decreased when the frequency distributions are known for all the shovel production formula factors. This shovel production formula for annual production rate can be divided into three main pillars. These three pillars are the hourly production rate, use of availability, and mechanical availability. The pillars allow OEMs or mining companies to implement the correct improvement measures to improve shovel productivity. However, one solution for every mining operation will be impossible due to the uncertainty in the data and variability of each mining operation.
To conclude, the factors that contribute to deviations from the predicted performance are categorised as uncontrollable (weather and geographical location), direct (density and cycle time), and indirect (fragmentation and face dimensions), which all impact shovel productivity. The most significant factors are not found during the study, but solving underperformance in the direct factors will solve most of the problems. The effect of automated trucks on shovel productivity will result in additional trucking capacity, which will need to be absorbed by the shovel. Lastly, a data-driven model can be developed with access to all the data from a mining operation. However, this data is often not available to an OEM. Therefore, it is not advisable to develop such a model. ...
The following research questions will be answered in this study: What factors contribute to deviations from the predicted performance? What factors are the most significant? What is the effect of automated trucks on shovel productivity? Can a data-driven model be developed to predict the actual productivity of the shovel in the real world?
The underlying causes of reduced shovel production are assessed through a literature review and five case studies. The case studies consisted of three data analytical desk studies, interviews with industry professionals, and a mine visit to north Africa.
The literature review shows that the mining industry uses formulas to determine the theoretical production rates. The factors in the shovel production formula should be predicted with frequency distributions. Also, truck automation will increase trucking hours, impacting shovel productivity through truck exchange time. The first case study shows a sensitivity analysis of the shovel formula. This sensitivity analysis shows that the swell factor, density, bucket fill, efficiency, and cycle time have a more significant impact than truck exchange time, dumping of the first bucket, and the number of cycles. The second case study shows the underperformance of different electric rope shovel models in different mining operations. The third case study compares the theoretical shovel capacity with the total material moved for 16 years. This shovel capacity and total material ratio should be between 1-2.5 for a mining operation to be classified as above-average-in-class. The fourth case study shows the different factors influencing shovel productivity based on the interviewees' responses. The last case study shows the effects of operational decisions on a mining operation. The literature review and case studies are used to develop a flowchart regarding the factors influencing shovel productivity.
This flowchart was used to synthesise the results. The difference between theoretical and real-world production rates can be decreased when the frequency distributions are known for all the shovel production formula factors. This shovel production formula for annual production rate can be divided into three main pillars. These three pillars are the hourly production rate, use of availability, and mechanical availability. The pillars allow OEMs or mining companies to implement the correct improvement measures to improve shovel productivity. However, one solution for every mining operation will be impossible due to the uncertainty in the data and variability of each mining operation.
To conclude, the factors that contribute to deviations from the predicted performance are categorised as uncontrollable (weather and geographical location), direct (density and cycle time), and indirect (fragmentation and face dimensions), which all impact shovel productivity. The most significant factors are not found during the study, but solving underperformance in the direct factors will solve most of the problems. The effect of automated trucks on shovel productivity will result in additional trucking capacity, which will need to be absorbed by the shovel. Lastly, a data-driven model can be developed with access to all the data from a mining operation. However, this data is often not available to an OEM. Therefore, it is not advisable to develop such a model. ...
The goal of a mining operation is to extract the maximum value from exploiting the orebody. The equipment used by these mining operations has a nominally rated performance to achieve needed annual production. However, this nominally rated performance is not achieved during operations. This study assesses the underlying causes of reduced shovel production in a mining operation.
The following research questions will be answered in this study: What factors contribute to deviations from the predicted performance? What factors are the most significant? What is the effect of automated trucks on shovel productivity? Can a data-driven model be developed to predict the actual productivity of the shovel in the real world?
The underlying causes of reduced shovel production are assessed through a literature review and five case studies. The case studies consisted of three data analytical desk studies, interviews with industry professionals, and a mine visit to north Africa.
The literature review shows that the mining industry uses formulas to determine the theoretical production rates. The factors in the shovel production formula should be predicted with frequency distributions. Also, truck automation will increase trucking hours, impacting shovel productivity through truck exchange time. The first case study shows a sensitivity analysis of the shovel formula. This sensitivity analysis shows that the swell factor, density, bucket fill, efficiency, and cycle time have a more significant impact than truck exchange time, dumping of the first bucket, and the number of cycles. The second case study shows the underperformance of different electric rope shovel models in different mining operations. The third case study compares the theoretical shovel capacity with the total material moved for 16 years. This shovel capacity and total material ratio should be between 1-2.5 for a mining operation to be classified as above-average-in-class. The fourth case study shows the different factors influencing shovel productivity based on the interviewees' responses. The last case study shows the effects of operational decisions on a mining operation. The literature review and case studies are used to develop a flowchart regarding the factors influencing shovel productivity.
This flowchart was used to synthesise the results. The difference between theoretical and real-world production rates can be decreased when the frequency distributions are known for all the shovel production formula factors. This shovel production formula for annual production rate can be divided into three main pillars. These three pillars are the hourly production rate, use of availability, and mechanical availability. The pillars allow OEMs or mining companies to implement the correct improvement measures to improve shovel productivity. However, one solution for every mining operation will be impossible due to the uncertainty in the data and variability of each mining operation.
To conclude, the factors that contribute to deviations from the predicted performance are categorised as uncontrollable (weather and geographical location), direct (density and cycle time), and indirect (fragmentation and face dimensions), which all impact shovel productivity. The most significant factors are not found during the study, but solving underperformance in the direct factors will solve most of the problems. The effect of automated trucks on shovel productivity will result in additional trucking capacity, which will need to be absorbed by the shovel. Lastly, a data-driven model can be developed with access to all the data from a mining operation. However, this data is often not available to an OEM. Therefore, it is not advisable to develop such a model.
The following research questions will be answered in this study: What factors contribute to deviations from the predicted performance? What factors are the most significant? What is the effect of automated trucks on shovel productivity? Can a data-driven model be developed to predict the actual productivity of the shovel in the real world?
The underlying causes of reduced shovel production are assessed through a literature review and five case studies. The case studies consisted of three data analytical desk studies, interviews with industry professionals, and a mine visit to north Africa.
The literature review shows that the mining industry uses formulas to determine the theoretical production rates. The factors in the shovel production formula should be predicted with frequency distributions. Also, truck automation will increase trucking hours, impacting shovel productivity through truck exchange time. The first case study shows a sensitivity analysis of the shovel formula. This sensitivity analysis shows that the swell factor, density, bucket fill, efficiency, and cycle time have a more significant impact than truck exchange time, dumping of the first bucket, and the number of cycles. The second case study shows the underperformance of different electric rope shovel models in different mining operations. The third case study compares the theoretical shovel capacity with the total material moved for 16 years. This shovel capacity and total material ratio should be between 1-2.5 for a mining operation to be classified as above-average-in-class. The fourth case study shows the different factors influencing shovel productivity based on the interviewees' responses. The last case study shows the effects of operational decisions on a mining operation. The literature review and case studies are used to develop a flowchart regarding the factors influencing shovel productivity.
This flowchart was used to synthesise the results. The difference between theoretical and real-world production rates can be decreased when the frequency distributions are known for all the shovel production formula factors. This shovel production formula for annual production rate can be divided into three main pillars. These three pillars are the hourly production rate, use of availability, and mechanical availability. The pillars allow OEMs or mining companies to implement the correct improvement measures to improve shovel productivity. However, one solution for every mining operation will be impossible due to the uncertainty in the data and variability of each mining operation.
To conclude, the factors that contribute to deviations from the predicted performance are categorised as uncontrollable (weather and geographical location), direct (density and cycle time), and indirect (fragmentation and face dimensions), which all impact shovel productivity. The most significant factors are not found during the study, but solving underperformance in the direct factors will solve most of the problems. The effect of automated trucks on shovel productivity will result in additional trucking capacity, which will need to be absorbed by the shovel. Lastly, a data-driven model can be developed with access to all the data from a mining operation. However, this data is often not available to an OEM. Therefore, it is not advisable to develop such a model.
A pilot research was set up to determine the possibilities for using gamma-ray spectrometry to and possible value in mine waste piles. These waste piles consist of different waste rocks without any value and ore that was processed incorrectly. This method, if proven eective, will be used on mine waste from different commodities all over the world. However, there will be started with the waste pile Halde Haniel in the Ruhr area in Germany. The Ruhr area has been selected because of the manageable travelling time from Delft, the long history of coal mining activities in the area and the open-access of the waste pile. The thriving days of coal mining have left us with large amounts of waste piles (170 waste piles in the Ruhr area). Therefore, it will be essential to know if these waste piles have an impact on the environment by emitting gamma radiation. In Europe, this problem has not been addressed. However, in other countries, these waste piles are the cause of increased health risks. The Halde Haniel waste pile is a human-made object and consist mainly of shale, sandstone and bits of coal. Gamma-ray spectrometry is often used to determine lithology of a rock formation. To determine the lithology measurements are done on outcrops present in nature. In most literature gamma-ray spectrometry is used to determine the lithology of rock formations. However, in this research, the measuring location is a human-made object, which has destroyed the natural sequencing of the rocks. Therefore, the measurements taken on the Halde Haniel makes the research more challenging. Therefore, the accuracy of the measurements done on a site consisting of multiple rocks, such as the Halde Haniel, are essential to know in order to apply this method in future research. Field measurements were taken for two dierent reasons. First, a control study was executed in the Green Village in Delft. The main goal of these measurements was to select a correct measuring time for the measurements at the Halde Haniel waste pile. The rest of the measurements were done at the Halde Haniel waste pile. At the Halde Haniel waste pile, four dierent measuring locations were selected. From the results can be concluded that the amount of gamma radiation emitted from the Halde Haniel waste pile is higher than at a location without mining activities. However, this increase is still not high enough to result in health risks. The measuring error could not be determined to a satisfactory standard, because of the lack of soil moisture samples and the signicant impact of soil moisture on the error of measurements. Gamma-ray spectrometry should be supported with information about the lithology and the chemical composition of the rocks, because otherwise nding value in waste piles will be hard.
...
A pilot research was set up to determine the possibilities for using gamma-ray spectrometry to and possible value in mine waste piles. These waste piles consist of different waste rocks without any value and ore that was processed incorrectly. This method, if proven eective, will be used on mine waste from different commodities all over the world. However, there will be started with the waste pile Halde Haniel in the Ruhr area in Germany. The Ruhr area has been selected because of the manageable travelling time from Delft, the long history of coal mining activities in the area and the open-access of the waste pile. The thriving days of coal mining have left us with large amounts of waste piles (170 waste piles in the Ruhr area). Therefore, it will be essential to know if these waste piles have an impact on the environment by emitting gamma radiation. In Europe, this problem has not been addressed. However, in other countries, these waste piles are the cause of increased health risks. The Halde Haniel waste pile is a human-made object and consist mainly of shale, sandstone and bits of coal. Gamma-ray spectrometry is often used to determine lithology of a rock formation. To determine the lithology measurements are done on outcrops present in nature. In most literature gamma-ray spectrometry is used to determine the lithology of rock formations. However, in this research, the measuring location is a human-made object, which has destroyed the natural sequencing of the rocks. Therefore, the measurements taken on the Halde Haniel makes the research more challenging. Therefore, the accuracy of the measurements done on a site consisting of multiple rocks, such as the Halde Haniel, are essential to know in order to apply this method in future research. Field measurements were taken for two dierent reasons. First, a control study was executed in the Green Village in Delft. The main goal of these measurements was to select a correct measuring time for the measurements at the Halde Haniel waste pile. The rest of the measurements were done at the Halde Haniel waste pile. At the Halde Haniel waste pile, four dierent measuring locations were selected. From the results can be concluded that the amount of gamma radiation emitted from the Halde Haniel waste pile is higher than at a location without mining activities. However, this increase is still not high enough to result in health risks. The measuring error could not be determined to a satisfactory standard, because of the lack of soil moisture samples and the signicant impact of soil moisture on the error of measurements. Gamma-ray spectrometry should be supported with information about the lithology and the chemical composition of the rocks, because otherwise nding value in waste piles will be hard.