SPECIALIST EQUIPMENT


RAPID REPAIR SOLUTION


Jamie Hutchinson reveals how primary crusher foundations were saved by polymeric concrete solutions


I


t’s not uncommon to have various problems that could be associated with machinery and equipment in the mining industry. T e environments in which they operate can be incredibly harsh, often leading to the need for repair and maintenance. T e most common issues associated within the mining industry include abrasion, chemical attack, corrosion, impact and wear. T ese can all have a major impact on processing and productivity. Ultimately, they can lead to shutdowns and costly downtime. A common cause of wear can be vibration. T is can cause eventual fatigue, resulting in cracks and a loss of material. Inherent vibration from the operational equipment can cause premature failures in areas such as concrete foundations and their anchoring systems. Generally speaking, concrete can be considered too brittle and weak to absorb such constant impact and vibration transferred from the equipment. Once the concrete has failed, anchor bolts in the foundations can loosen, further aggravating the eff ects of the vibration on the foundation.


CASE IN POINT A copper mine in Marabá, Brazil, found this to be the case with its primary


The initial damage Slurry mix of Belzona 4111 being applied


crusher. T e base of the primary crusher needed to be rebuilt due to being weakened by vibration. T e primary crusher weighs 336 tonnes and is 9.5m high and 5.6m wide, contributing further to the amount of stress being put on the foundations. T e crusher processes over 3,000 tonnes of copper ore per hour. Being one of the biggest copper crushers in South America, and with copper being traded at around US$6,000 per tonne, every hour of shutdown can result in a loss of almost US$20 million. Continuing under such damaged conditions would have eventually led to serious consequences, including a signifi cant fi nancial loss. A solution was required that could rebuild the foundation and bases of the primary crusher, whilst being able to withstand high dynamic and impact loads without shattering and breaking. Excellent mechanical properties and a fast curing time were also critical in ensuring the primary crusher would return to service in as little time as possible. T e solution used was Belzona 4111 (Magma Quartz), a high-performance concrete repair and rebuild composite. Using an impact hammer drill,


the fi rst two layers of concrete were removed to reach the steel reinforcement structure. Particularly with concrete


repairs, surface preparation is critical in its success. T e substrate needs to be free from contamination, free from excess moisture and any loose material needs to be removed. T e area was therefore cleaned and degreased with solvent and compressed air was used to remove the entire repair area of loose debris and dust. A conditioner was then applied to ensure an optimum bond between the substrate and repair materials. T e perimeter of the repair area was initially built up, later acting as a mould for a slurry mix of Belzona 4111. T e material was able to level evenly to recreate a foundation at the base of the primary crusher. T e implemented solution off ered resistance to high vibrations and dynamic loads due to its high mechanical strength. T e system adhered to both metal and old concrete allowing for a homogeneous load distribution, without weak spots during the anchoring/grouting procedure and service. T e assembly of the machine commenced in as little as four to six hours after application and a full return to service was possible in approximately 16 hours. T e fast turnaround time allowed the copper mine to continue its processes without a majorly disruptive or costly downtime.


The repair still performing perfectly


Jamie Hutchinson is with Belzona. www.belzona.com


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