TY - JOUR
T1 - Dry sliding wear of aluminium-high silicon hypereutectic alloys
AU - Alshmri, F.
AU - Atkinson, H. V.
AU - Hainsworth, S. V.
AU - Haidon, C.
AU - Lawes, S. D A
PY - 2014/5/15
Y1 - 2014/5/15
N2 - One of the main limitations on using aluminium-high silicon (with silicon contents greater than about 20. wt%) alloys is the formation of coarse, brittle silicon particles under conventional solidification conditions. However, an increase in silicon content generally gives an improvement in wear properties so there is a drive to produce the high silicon alloys with relatively fine microstructures. Rapid solidification processing (RS) is very effective in limiting the coarsening of primary silicon due to the high cooling rate. Here flakes of material produced by chopping melt-spun ribbon have been degassed, consolidated, hot isostatically pressed and then extruded. The resulting material has been subjected to dry sliding reciprocating multi-pass wear testing at room temperature against a steel ball bearing at 10N and 100N load. The alloys compared can essentially be characterised as 'low in silicon (around 21. wt%), high in intermetallic-forming elements (Fe, Cu, Ni)' and 'high in Si (around 30. wt% Si), low in intermetallic forming elements'. The wear results show that extruded bar with composition Al 21Si 3.9Cu 1.2. Mg 2.4Fe 1.4Ni 0.4Zr has higher hardness, and hence wear resistance, than extruded bar with composition Al 29.8Si 1.3Cu 1.4. Mg 0.3Fe 0.3Ni 0.3Zr, despite the higher Si content. It is thought that, at the higher Si content, there may be silicon particle pull-out which may subsequently lead to a three-body abrasive wear mechanism. In addition, for the lower Si alloy, the higher amounts of intermetallic-forming elements are thought to be contributing to the wear resistance.
AB - One of the main limitations on using aluminium-high silicon (with silicon contents greater than about 20. wt%) alloys is the formation of coarse, brittle silicon particles under conventional solidification conditions. However, an increase in silicon content generally gives an improvement in wear properties so there is a drive to produce the high silicon alloys with relatively fine microstructures. Rapid solidification processing (RS) is very effective in limiting the coarsening of primary silicon due to the high cooling rate. Here flakes of material produced by chopping melt-spun ribbon have been degassed, consolidated, hot isostatically pressed and then extruded. The resulting material has been subjected to dry sliding reciprocating multi-pass wear testing at room temperature against a steel ball bearing at 10N and 100N load. The alloys compared can essentially be characterised as 'low in silicon (around 21. wt%), high in intermetallic-forming elements (Fe, Cu, Ni)' and 'high in Si (around 30. wt% Si), low in intermetallic forming elements'. The wear results show that extruded bar with composition Al 21Si 3.9Cu 1.2. Mg 2.4Fe 1.4Ni 0.4Zr has higher hardness, and hence wear resistance, than extruded bar with composition Al 29.8Si 1.3Cu 1.4. Mg 0.3Fe 0.3Ni 0.3Zr, despite the higher Si content. It is thought that, at the higher Si content, there may be silicon particle pull-out which may subsequently lead to a three-body abrasive wear mechanism. In addition, for the lower Si alloy, the higher amounts of intermetallic-forming elements are thought to be contributing to the wear resistance.
KW - Aluminium-high si alloys
KW - Electron microscopy
KW - Non-ferrous metals
KW - Sliding wear
KW - Wear testing
UR - http://www.scopus.com/inward/record.url?scp=84896343835&partnerID=8YFLogxK
UR - https://www.sciencedirect.com/science/article/pii/S0043164814000544?via%3Dihub
U2 - 10.1016/j.wear.2014.02.010
DO - 10.1016/j.wear.2014.02.010
M3 - Article
AN - SCOPUS:84896343835
SN - 0043-1648
VL - 313
SP - 106
EP - 116
JO - Wear
JF - Wear
IS - 1-2
ER -