Effect of Deadweight on Frame and Correlation with Human Passenger in
a Two Wheeler 2023-01-5080
Deadweight as payload is an important parameter, which affects the vehicle
dynamics and durability of the vehicle. This paper presents a study performed to
evaluate the effect of deadweight on dynamic input load, suspension operation,
and fatigue life of frame in a two wheeler. Also, an optimization exercise was
undertaken to correlate and optimize deadweight with a human payload in terms of
equivalent damage to the frame. Strain, wheel acceleration, and suspension
displacement data were acquired with pillion and multiple deadweights and
compared. Relative damage spectrum (RDS) characterization and best-fit
optimization methods were used for deadweight correlation. It was observed that
with deadweight addition dynamic loads decreases on the front wheel while
increases on the rear. Strain damage wise increasing deadweights have marginal
effects on the front zone of the frame while on the middle and rear side,
deadweights are detrimental. Human payload behaves like deadweight for dynamic
loading as observed with higher acceleration and suspension stroke level given
its magnitude, but in terms of strain damage it has very low damaging effect as
compared to deadweights. Deadweight optimization exercise suggested an optimum
weight to have an equivalent damage for the same durability cycle as human
pillion. The study aimed to help in understanding the design load considerations
taking deadweight into account as well as in the development of proving ground
test cycle with deadweight as a human substitute. The latter could be applied in
case of manpower planning or pandemic scenario such as COVID-19.