Achieve greater visibility at scale to confirm stability
In underground mining rock mass displacement from an excavation can have significant consequences, from injuring personnel to causing unscheduled delays, with the subsequent cost implications.
In a mine you can rarely predict where things are going to change dramatically, therefore the ability to efficiently and effectively monitor change and convergence across the whole excavation is vital to safeguard against incidents and mitigate impacts on production and therefore profitability.
However, only a fraction of the cubic kilometers affected by the mining process are observable through drill holes or excavation fronts and therefore capturing sufficient data to be able to confirm that all areas of an excavation are stable can be challenging.
Additionally, processing the data to achieve analysis-ready outputs is a highly time consuming and manual process. As a result, many mining operations are falling short in the frequency and extent of their monitoring efforts, often unable to meet the standards they aspire to or that are necessary for optimal safety and operational efficiency.
The limitations of traditional methods
Currently, the predominant method for assessing change in underground mining is damage mapping, which entails annotating two-dimensional section views of the mine to highlight areas of damage. While this approach allows for coverage of a considerable area, it is subject to human error. Alternatively, tape or digital extensometers are used to measure specific points within the mine. Although these devices offer high levels of accuracy, due to the heterogeneous nature of rock masses, which exhibit varying properties across different locations within drives, tunnels, or cross-sections, the results cannot represent change across an entire excavation. More advanced technologies such as total stations or fixed laser sensors are highly accurate, however, they are constrained by limited coverage capabilities.
While each of these methods has its place, they also have their limitations. As a result, many underground mines fall short in the scale, frequency and reliability of their monitoring efforts, putting safety and profitability at risk.
Complementing traditional methods with SLAM
Complementing traditional practices with a SLAM methodology allows the implementation of an improved overall monitoring plan. For example, SLAM can quickly map an entire mine and identify displacement with moderate to high accuracy. This provides more accurate and quantitative data than damage mapping.
When it comes to tape extensometers, a SLAM map of an entire mine will allow you to pinpoint exactly where to use an extensometer in future to confirm that displacement. Or a total station could be used to identify change regarding specific infrastructure, for example a 1-2mm (about 0.08 in) shift at a mine entrance, but SLAM complements this by scaling to rapid mapping of large areas. Similarly, a fixed laser could be used to ensure a crusher chamber is not moving too much during stoping for example, but SLAM can be used to cover a wider area.
While many mines have used SLAM technology to scan the entire site and establish a baseline, alignment of these scans is a time consuming and manual process that usually requires the use of complex third-party software.
In underground mining rock mass displacement from an excavation can have significant consequences, from injuring personnel to causing unscheduled delays, with the subsequent cost implications.
In a mine you can rarely predict where things are going to change dramatically, therefore the ability to efficiently and effectively monitor change and convergence across the whole excavation is vital to safeguard against incidents and mitigate impacts on production and therefore profitability.
However, only a fraction of the cubic kilometers affected by the mining process are observable through drill holes or excavation fronts and therefore capturing sufficient data to be able to confirm that all areas of an excavation are stable can be challenging.
Additionally, processing the data to achieve analysis-ready outputs is a highly time consuming and manual process. As a result, many mining operations are falling short in the frequency and extent of their monitoring efforts, often unable to meet the standards they aspire to or that are necessary for optimal safety and operational efficiency.
The limitations of traditional methods
Currently, the predominant method for assessing change in underground mining is damage mapping, which entails annotating two-dimensional section views of the mine to highlight areas of damage. While this approach allows for coverage of a considerable area, it is subject to human error. Alternatively, tape or digital extensometers are used to measure specific points within the mine. Although these devices offer high levels of accuracy, due to the heterogeneous nature of rock masses, which exhibit varying properties across different locations within drives, tunnels, or cross-sections, the results cannot represent change across an entire excavation. More advanced technologies such as total stations or fixed laser sensors are highly accurate, however, they are constrained by limited coverage capabilities.
While each of these methods has its place, they also have their limitations. As a result, many underground mines fall short in the scale, frequency and reliability of their monitoring efforts, putting safety and profitability at risk.
Complementing traditional methods with SLAM
Complementing traditional practices with a SLAM methodology allows the implementation of an improved overall monitoring plan. For example, SLAM can quickly map an entire mine and identify displacement with moderate to high accuracy. This provides more accurate and quantitative data than damage mapping.
When it comes to tape extensometers, a SLAM map of an entire mine will allow you to pinpoint exactly where to use an extensometer in future to confirm that displacement. Or a total station could be used to identify change regarding specific infrastructure, for example a 1-2mm (about 0.08 in) shift at a mine entrance, but SLAM complements this by scaling to rapid mapping of large areas. Similarly, a fixed laser could be used to ensure a crusher chamber is not moving too much during stoping for example, but SLAM can be used to cover a wider area.
While many mines have used SLAM technology to scan the entire site and establish a baseline, alignment of these scans is a time consuming and manual process that usually requires the use of complex third-party software.
Optimized for enclosed spaces and underground mines, and applicable to both hard rock (change detection) and soft rock (convergence monitoring) mines, Emesent’s Change Detection and Convergence Monitoring solution combines rapid capture mobile SLAM technology with a faster, easier and more repeatable processing workflow. This enables mining operators to scan excavations over a larger area more regularly and monitor change using accurate, quantitative data.
The solution eliminates the need for data segmentation, manual alignment or third party software and requires minimal user input. This ultimately delivers more repeatable, quantifiable outputs on where change or dilation is occurring and the velocity of this change over a large area. This can then be combined with other data to determine root cause analysis or identify why that change is occurring, allowing for more regular and widespread monitoring of change, helping engineers – from geotechs to surveyors – to make more informed decisions and reduce risk.
The solution eliminates the need for data segmentation, manual alignment or third party software and requires minimal user input. This ultimately delivers more repeatable, quantifiable outputs on where change or dilation is occurring and the velocity of this change over a large area. This can then be combined with other data to determine root cause analysis or identify why that change is occurring, allowing for more regular and widespread monitoring of change, helping engineers – from geotechs to surveyors – to make more informed decisions and reduce risk.
The Emesent Solution
Allows quantitative and repeatable interpretation of deformation across an entire excavation.
Quantitative results
Compares scans of continuous 3D data at the same time. A non-rigid alignment process avoids segmentation to adjust for scan drift.
No need to segment data
Eliminates complex and time-consuming 3rd party software for alignment of scans.
No 3rd-party software
Process, align and visualize changes between two Hovermap scans.
Streamlined workflow
Rapidly capture current excavation profiles with Hovermap.
Rapid data capture
Enables large scale and regular monitoring, delivering data to improve engineer decision making to reduce risk and hazard exposure.
Large-scale monitoring
Process and align scans directly in Emesent software.
Data processing
Generate quantitative insights to support engineering decisions.
Reporting
Сравнивайте сканы для выявления деформаций и изменений со временем.
Analysis of changes
Use Hovermap to capture 3D scans of your mine.
Data collection
Rapid insights with applications across every type of underground mine that can be fed into a range of engineering processes.
Improve your monitoring program
Check for change in crib rooms, crusher chambers, conveyor drives and portals.
Internal Enclosed Spaces
Back analysis, identification of post-event changes.
Mines in Active Seismic Areas
Monitor for ongoing change around discontinuities, large structure and bulking surface support.
Deep / High Stress Mines
Rapidly identify large stress changes and monitor long-life excavations.
Caving Operations
Check the condition of oredrives, brows and high exposure excavations.
Frequent Stope Blasting
Monitor all excavation to check stability and ensure a safe workplace
All Active Workings
Mon-Fri: 09.00 - 18.00
RK, Ust-Kamenogorsk, st. Tokhtarova, 51, off. 50
line of business
©2025. Alpha-Safety. All rights reserved.
