Numerical Analysis and Material Testing of Failure Coach Axle
Axle is an important component of a train and directly related to train operation safety. There are two forms of passenger train axle failure the first axle broken with the fracture surface perpendicular to axle axis, showing fatigue failure and the second axle broken in the bearing area with a f...
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| Format: | Theses |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/44423 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Axle is an important component of a train and directly related to train operation
safety. There are two forms of passenger train axle failure the first axle broken with the
fracture surface perpendicular to axle axis, showing fatigue failure and the second axle
broken in the bearing area with a form that shows axle suffered wear, heat treatment and
plastic deformation (hot axle). To prevent and avoid similar failures happening again it is
necessary to conduct root cause analysis study of passenger train axle failure.
Through this study is expected the axle failure phenomenon can be understood.
The root causes of the hot axle and broken axle can be found. The final objective is an
alternative step and recommendations on corrective and prefentif required.
In this research, literature study about previous axle failures on the train has been,
conducted to study the phenomenon of axle failures. Surveys and interviews conducted on
the wheel sets maintenance facilities to determine condition of axle maintenance and to
observe axle failure mode. Stress analysis of axle conducted to get the performance of
axle on normal loading conditions, in bad condition of rail connections and damaged on
wheel roundness profile. Microstructure and hardness testing of failed axle specimens is
performed to determine the material condition of the failure axle. Through the above
activities we can obtain axle failure main cause.
The stress analysis of axle on ideal loading conditions shows the maximum
principal stress 89.9MPa. On loading with acceleration in the vertical direction for 2.5g (g
is the acceleration of gravity) on the axle stress greater than the endurance limit, so the
axle age is limited. Micro structure testing shows there are several layers of different
micro-structures on axle, micro-structural changes showed the effect of heat in the axle.
The results of tests on hot axle specimens found Widmanstatten structure which is an
indication that the axle material warming until 1000oC and then cooled in air. Heat comes
from friction between the bearing and the axle due to poor fit between bearings and axle.
Friction caused wear and high heat and cause axle failure. In broken axle sampel observed
axle fatigue failures caused by imperfections in the surface hardening process that resulted
in material softening on some position produce lower strength. Low strength can not
withstand the stress from the tensile residual stress in chrom plating and bending stress
due to load on the axle. To avoid the same failures happen improvement on axle and
bearing maintenance procedures and axle chromium plating procedures. |
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