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Mg alloys have vast applications in the automobile industry due to their attractive
properties such as outstanding stiffness/weight ratio, excellent castability, good damping
capacity and easy recyclability. Mg alloys such as AZ91, AZ31 and AM50 are widely used
for automobile components such as cam covers, baffles, oil adaptors, clutch housings and
roof frame assemblies. However, these alloys have limited opportunity in the powertrain
applications such as automatic transmission cases and engine blocks owing to the
degradation of their mechanical properties at high temperature. Due to their inferior
mechanical properties such as hardness, the tribological performance of Mg based alloys is
also not adequate for such applications.
A die casting alloy that was developed for high temperature applications is AE42.
This alloy contains 4 % Al and 2 % rare earth (RE) elements. The alloy is characterized by
the presence of elongated precipitates of β-Mg17Al12 and Al11RE3 as the major phase along
with Mg with an average grain size of nearly 20 μm. These precipitates are formed in-situ
during the transformation cooling of the alloy. The presence of elongated precipitates and
the coarse grain structure of the AE42 alloy have been reported to be detrimental to its
mechanical properties such as yield strength and hardness.
Ultra-fine grained (UFG) materials are known for their superior mechanical
properties in accordance with the Hall-Petch equation. Therefore, grain size refinement of
the material provides one of the possibilities by which material strengthening can be
achieved through grain boundary strengthening. The severe plastic deformation (SPD)
processes have successfully emerged as one of those processes that can develop UFG
structure in the materials in the bulk form. The most popular and successful SPD processes
are equal channel angular extrusion (ECAE), high pressure torsion (HPT), accumulative roll
bonding (ARB) and friction stir processing (FSP). Amongst all these process, FSP is the most recent SPD process that has evolved as the successful and versatile microstructural
refinement process.
In the current study, the influence of FSP on the microstructural, mechanical,
corrosion and tribological properties of AE42 alloy has been investigated. A specially
designed fixture was fabricated to clamp the AE42 samples on a vertical CNC milling
machine for performing FSP. The fixture had a hollow rectangular box configuration and
was connected to an external chiller unit for undersurface cooling of the friction stir
processed (FSPed) specimens. The medium used for cooling was methanol and it was
circulated at -20° C.
The in-depth studies of the microstructural changes that took place during FSP of the
investigated alloy were done using SEM/EDS, XRD, TEM, FIB-SIMS and EBSD analyses.
The microstructural observations revealed the occurrence of significant microstructural
refinement in the FSPed region. The elongated precipitates were fragmented and some new
in-situ precipitates were generated. The precipitate size got further refined with more
number of FSP passes. It was found to vary from 200 nm – 1 μm range in single pass FSP to
as fine as 50 nm with double pass FSP as compared to about 80 – 90 μm size precipitates in
the as-cast alloy. The grain size also got considerably refined during FSP, the extent of
which was found to vary with the FSP parameters. TEM, FIB-SIMS as well as EBSD
analysis of the FSPed alloy also showed the presence of submicron grains in the FSPed
alloy, the percentage of which further increased with increase in number of FSP passes
supplemented by undersurface cooling. The microstructural refinement resulted in nearly 60
% enhancement in the hardness of the FSPed alloy. The major factor that contributed to the
enhanced hardness of the FSPed alloy was found to be grain size strengthening. EBSD
results showed that the grain size varies along the depth of the specimen cross-section. The
grain size was found to be more refined with increase in distance from the FSP tool
shoulder. The EBSD results also confirmed the occurrence of texture variations across the
depth of the FSPed alloy.
For determining the most influential FSP parameters effecting the properties of
FSPed AE42 alloy, the FSP parameters were varied over a range and a systematic evaluation
of these parameters using Taguchi’s DOE technique was done. The most influential
parameters were found to be cooling temperature, FSP tool rpm and number of FSP passes. FSP specimens were processed at the optimized set of FSP parameters and mechanical
properties were determined using tensile testing, bulkhardness testing and scratch test. The
FSPed specimens sowed enhanced scratch resistance and enhanced hardness. The other
mechanical properties such as yield strength and ultimate strength got considerably
enhanced without comprising the ductility. Instead, the FSPed specimen showed a little
improvement in the percentage elongation also. The microstructural studies of the fractured
surfaces showed brittle and ductile failure for the as-cast and FSPed AE42 alloy
respectively. Further, the FSPed alloy also exhibited greater strain hardening as compared to
the as-cast alloy.
Attempt has been made in the current study to simulate the thermal history during
FSP using a novel technique of developing finite difference equations (FDE’s). The crosssection
of the FSPed specimen was divided into discrete number of nodes in the x and y
directions. FDE’s were written for each of the nodes and were expressed in the matrix form
separating the variables, constants and the temperature terms. The major source of heat
during FSP was considered to be the frictional heat between the FSP tool shoulder and
workpiece. The variation of axial load at different FSP parameters, required for evaluation
of heat input, was determined using a tool dynamometer. A generalized MATLAB code was
written for the simultaneous solution of all the FDE’s. The code was generalized in terms of
number of nodes and the FSP parameters such as FSP tool rpm, linear speed and axial load.
The validation of the numerical simulation of thermal history was done by comparison with
the experimental temperature values, determined at different FSP parameters. The actual
temperature values were determined using K type thermocouples and data acquisition
system. The numerical simulation was found to predict the thermal history at different FSP
parameters to a fairly acceptable accuracy with error ranging from nearly 2 to 9 %.
Prediction of thermal history using numerical simulation approach assumed that the
heat input across the tool shoulder is constant. The effect of viscous heat dissipation was
also neglected. However, the heat input varies across the tool shoulder. To consider the
influence of variable heat input, effect of viscous heat dissipation and determination of
certain other important parameters such as velocity and strain rates, FSP simulation was also
done using FLUENT software. The thermal history predicted using numerical simulation was further used for the estimation of the grain growth rates and final recrystallized grain
size of the FSPed AE42 alloy under different FSP conditions.
The corrosion behaviour of the as-cast as well as FSPed AE42 alloy was investigated
using corrosion immersion and electrochemical corrosion tests in 3.5 % NaCl solution. The
first phase of the analysis involved determination of set of FSP parameters which can induce
maximum corrosion resistance in the AE42 alloy using DOE technique. The second phase of
the analysis involved elaborate study of the as-cast and the FSPed specimen that has shown
higher corrosion resistance in the first phase. The immersion carrion tests were performed
for a period of 48 hours. Weight loss after different time intervals was used for calculating
the corrosion rates. The corroded surfaces were analyzed using SEM/EDS. Electrochemical
corrosion studies viz potentiodynamic polarization, Rp/Ec and electrochemical impedance
spectroscopy (EIS) were conducted on as-cast as well as FSPed AE42 specimens. The tests
were performed on a Gamry’s electrochemical workstation using a three electrode cell
consisting of saturated calomel electrode (SCE) as a reference electrode, graphite as a
counter electrode and as-cast/FSPed AE42 specimen as a working electrode in a 3.5 % NaCl
solution. The FSPed alloy showed a higher corrosion resistance in comparison with the ascast
alloy. Further, the corrosion rate was found to decrease with decrease in the grain size
of the FSPed alloy. The stability of oxide layer in 3.5 % NaCl solution was attributed to the
presence of uniformly distributed fine in-situ precipitates.
The tribological performance of the as-cast and FSPed AE42 alloys was evaluated
using pin-on-disc wear tests. The tests were performed at different sliding velocities and
normal loads, which varied from 0.33 m/s to 3 m/s and 5 N to 20 N respectively. The tests
were performed for a constant sliding distance of 2.5 Km. Worn surfaces and wear debris
were analyzed using SEM and EDS for the determination of different wear mechanisms.
The subsurface analysis of the worn surfaces revealed higher work-hardening capability of
the FSPed alloy. The FSPed AE42 alloy demonstrated atleast 23 % decrease in the wear rate
in comparison with its as-cast counterpart, which may be attributed to the microstructural
refinement resulting in enhanced hardness and ductility of the FSPed alloy along with higher
work hardening capability. At low loads, wear mechanism transformed from oxidation and
abrasive wear at low sliding velocity to delamination at high velocity. At intermediate loads,
oxidation and abrasion characterized the worn surface at low velocity, whereas delamination and plastic deformation were found to be major wear mechanisms at high velocities. At high
loads, the corresponding mechanisms were abrasion, delamination and plastic deformation
at low velocity, whereas severe plastic deformation and delamination at high velocities.
Based on the overall results of the present study, a set of FSP parameters may be
recommended for the given Mg-based AE42 alloy, which comprises tool rotational speed of
700 rpm, a cooling temperature of -10° C, a linear speed of 60 mm/min and FSP passes as 3.
With these parameters, the bulk hardness of the alloy could be enhanced by 60 %, whereas a
reduction of atleast 23 % in the wear rate could be achieved. Moreover, the corrosion rate of
the alloy in 3.5 % NaCl solution could be reduced by 50 % by its FSP at these parameters. |
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