Abstract
The wear and friction in the pitch region of the centre of polymer gear teeth are not well understood. The transition around this point of the tooth between rolling and sliding has an important effect on the durability of polymer gear drives and can be simulated using a twin-disc configuration. This paper investigates the rolling–sliding wear behaviour of two poly-ether-ether-ketone (PEEK) discs running against each other with a simplified method of analysing and understanding the dynamic response of high performance polymeric gear teeth.Tests were conducted without external lubrication over a range of loads and slip ratios, using a twin-disc test rig. The wear and friction mechanisms were closely related to surface morphology, with changes in crystallinity correlating with the severity of operating conditions. Observed failure mechanisms were also related to the structure of the contact surfaces, and included surface melting and contact fatigue.Overall the PEEK discs were capable of running at low slip ratios for both low and high loads. Their performance reduced with an increase of the slip ratio. The results presented can be used in conjunction with the design process to allow the PEEK to be engineered for a specific high performance gear contact conditions.
Highlights
With a growing awareness of engineering polymers, there is increasing application of polymers and polymeric composites to machine elements
Slip ratios in twin disc testing tend to be limited to around 30%, whereas slip ratios above 30% are found throughout the majority of the gear meshing cycle
Previous work, using the twin-disc configuration, has compared the tribological performance of a range of engineering polymers and their composites, namely polyoxymethylene (POM) [1,2], polyamide 46 (PA46) [3], polyamide 66 (PA66) [2,4,5,6], glass–fibre reinforced PA66 [2,7,8], PA66 and POM filled with 20 wt% of polytetrafluoroethylene (PTFE) [9], and short fibre, aramid and carbon-reinforced PA66 [3]
Summary
With a growing awareness of engineering polymers, there is increasing application of polymers and polymeric composites to machine elements. Previous work, using the twin-disc configuration, has compared the tribological performance of a range of engineering polymers and their composites, namely polyoxymethylene (POM) [1,2], polyamide 46 (PA46) [3], polyamide 66 (PA66) [2,4,5,6], glass–fibre reinforced PA66 [2,7,8], PA66 and POM filled with 20 wt% of polytetrafluoroethylene (PTFE) [9], and short fibre, aramid and carbon-reinforced PA66 [3] These materials were tested over a range of rolling speeds and slip-ratios to study their wear and frictional properties and their potential damage mechanisms
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