Take Control of Autonomous Haulage Stoppages with Powerful HRE

Australia
Take Control of Autonomous Haulage Stoppages with Powerful HRE 32% reduction in AHS-related stoppages, leading to improved productivity, reduced maintenance costs, and enhanced operational efficiency.

The Task

A mining operation was experiencing significant disruptions after its recent transition to an autonomous haulage system (AHS). Frequent stoppages due to various factors were hindering productivity and negatively impacting overall operations. To address these issues, the company implemented Haul Road Explorer (HRE) to help optimise its autonomous haulage systems and obtain the highest value possible.

Challenge

Following the transition from conventional to automated operational processes, the site was facing some issues with its new autonomous trucks. Due to the enhanced safety features and the lack of onboard human judgement, trucks would frequently stop across the site for a variety of reasons. For example, if a truck detected an object in the road, it would stop until it was cleared. A human driver would simply drive around the obstacle. This issue becomes particularly prevalent when perceived obstacles are identified to be vegetation, cables or wheel ruts, causing unnecessary and widespread stoppages.

It was important to better understand these stoppage events and gain deeper insight into them, in order to highlight their spatial distributions, resultant production losses and the areas of greatest concern.

Analysis

To address these issues, the site utilised Haul Road Explorer (HRE). It was incorporated to identify areas where obstacles were detected chronically, expanding bubbles, and other potential issues. By analysing data from various sources, including sensors, cameras, and communication networks, HRE provided valuable insights into the root causes of the AHS stoppages.

The initial analysis identified several key issues: 

  • Perceived Obstacles: Trucks were frequently stopping due to perceived obstacles, such as overhanging rocks, loose materials, or communication coverage gaps. These false positives were leading to unnecessary downtime and reduced efficiency.
  • Communication Issues: Communication black spots were causing intersecting expanding bubbles, leading to AHS stoppages. Expanding bubbles are the last known zone of an AHS asset after communication loss. If another truck enters this zone it will automatically stop to avoid collision. This was particularly problematic in areas with complex terrain or dense vegetation.
  • Infrastructure Limitations: Cable bridges were triggering object detection, leading to false alarms and stoppages. Additionally, dump cells were too close, resulting in sloughed material impacting subsequent dumps.
  • Operator Behaviour: Overloading by some operators was contributing to spillage and stoppages, creating additional challenges for the AHS.
  • Road Conditions: Ruts and uneven terrain were causing issues for the fleet, leading to increased maintenance costs and reduced vehicle lifespan. HRE was also able to determine the knock-on impact of stoppages, enabling the quantification of the impact on production. This provided insight into which areas/stoppage types contributed to the highest production loss and where increased monitoring should be employed.

The Solution

Key Findings and Actions

HRE’s analysis revealed several critical areas for improvement:

  • Infrastructure Optimisation: Communication black spots were identified and addressed by repositioning infrastructure and installing additional repeaters. Cable bridges were modified to prevent object detection issues including some problematic cables being buried, ultimately reducing false alarms.
  • Operational Adjustments: Operators were trained on best practices for loading and avoiding spillage. It also facilitates the identification of repeat offenders, allowing for ongoing targeted training. This helped to reduce the number of stoppages caused by material obstructions.
  • Road Improvements: Problematic areas with ruts were quickly identified, and efforts were made to re-engineer the roads where possible. This involved levelling the terrain, repairing potholes, and improving drainage.
  • Fleet Support: Increased support was provided to trucks operating in challenging areas, such as corners with ruts or steep inclines. 
  • Reaction Time Analysis: The site reviewed reaction times to clear obstacles, to identify areas for improvement in monitoring and response. This led to the implementation of more efficient procedures for clearing obstructions and minimising downtime.
  • Dump Cell Improvements: Dumping cells were identified to be too close together. Dumped material would slough into travel routes, confusing the autonomous systems for following dumps. The design process was refined to mitigate this issue.

The Results

The implementation of HRE and root cause identification resulted in a significant reduction in AHS-related stoppages. More specifically, the site achieved a 32% reduction in stoppages, leading to improved productivity, reduced maintenance costs, and increased overall operational efficiency.

Summary

By leveraging Haul Road Explorer, the mining operation was able to effectively identify and address the root causes of AHS stoppages. The implementation of targeted solutions led to a substantial improvement in operational efficiency and productivity. This case study demonstrates the power of data-driven insights in optimising autonomous haulage systems, ensuring uninterrupted operations and heightened maturity of the new system.