Mines are among the most demanding environments for structures and production equipment. Various factors, such as significant temperature variations, high humidity levels and the presence of chemical products and corrosive agents, impact the service life of structural components. Since these parts are often made of steel, they are susceptible to premature wear caused by corrosion. A structure affected by rust will require more maintenance and upkeep and can potentially be less safe.
Although recognized for its strength and advantageous mechanical properties, steel tends to corrode, particularly in environments where stressors promote the development of rust (high temperatures, high humidity levels and contact with corrosive agents). Rust is not only an aesthetic issue; it also affects the integrity of steel. The appearance of rust can cause steel to lose its mechanical properties and weaken metal structures..
As previously mentioned, steel is not the best material for mining environments; composite materials are by far more efficient and durable. For example, FRP (fibre reinforced plastic), a high-performance material, can easily replace steel when manufacturing structural elements. In fact, it is more than just a substitute; its properties surpass those of steel in a number of applications. When used in mining environments, FRP offers many advantages:
Although friction may be viewed as a minor issue with little influence on the production rate or the speed of bulk material transport, it is a critical aspect that should be addressed. In fact, optimizing your equipment to minimize friction will produce favourable results. While it is impossible to eliminate friction completely, it can be considerably reduced. In addition to prematurely wearing out parts and components, friction hinders the conveying and transportation of bulk material. For instance, the friction of raw materials against the walls of a chute spilling onto a conveyor generates friction, slowing down the flow of material. Minimizing friction improves the speed at which the material is unloaded onto the chute, thereby stabilizing the flow of material, eliminating system clogging and reducing the frequency of external interventions. It also reduces wear, resulting in fewer maintenance shutdowns.
Choose materials with low coefficients of friction. For example, a stainless steel chute can be easily optimized by attaching anti-friction liners to its walls. Performance plastics such as UHMW TIVAR 88-2 have been developed precisely for this purpose. TIVAR 88-2 is highly resistant to abrasion and promotes sliding, allowing the material to move on its surface more easily. Since the coefficient of friction of stainless steel is around 0.30, installing a TIVAR 88-2 liner, which has a coefficient of friction of 0.08, will significantly reduce friction. This UHMW can also be welded, making it possible to design liners that are perfectly adapted to your needs, regardless of the size or shape of the chute.
As most of you know, mining is a dangerous occupation. It is therefore important to reduce the risk of accidents caused by machinery, equipment, falls, noise, impacts and vibrations
To reduce the risks associated with equipment, machinery and conveyors, limiting access to moving parts is by far the most effective solution. For instance, protective guards, such as shields made of polycarbonate—a material as transparent as glass but 250 times more resistant to impact—can be installed.
It is also possible to limit access by using FRP gratings, which are lighter and more durable than metal ones, especially in conditions that are too demanding for metals. In addition, FRP gratings never rust and are stronger than those made of steel.
When affected by rust, structures, walkways, ladders and guardrails can increase the risk of falls.
To determine important factors that might influence your choice, please read our article, “4 Questions to Help You Choose the Right Structural Material.”
In addition to their poor resistance to corrosion, steel structures have rather limited anti-slip properties. Indeed, when used in humid and highly dusty environments, they become covered in a layer of fine particles, reducing their grip and increasing the risk of falls. FRP has a non-slip finish and is nonconductive, thus limiting the risk of same-level or lower-level falls.
Noise is one of the major causes of work-related accidents and occupational diseases. Exposure to high levels of noise has significant physical impacts.
If you would like to learn more on this topic, please read our article, “The Impact of Workplace Noise.”
Shocks and impacts caused by bulk material moving on conveyors and in metal chutes can generate noise levels that are above the acceptable threshold. In situations like these, polymer liners can be used to absorb impacts and thereby reduce noise levels. Plastics such as UHMWs are perfect for these types of applications.