Phase Detection Relevance in Engine Torque Determined by Instantaneous Engine Speed 2024-01-4270
Accurate flywheel torque estimation in combustion engines can be
used for monitoring engine performance, creating the potential for
lowering emissions and fuel costs. Recently a method was proposed to
determine the mean flywheel torque from instantaneous engine speed
using the n-th order Fourier series, where n is the number of cylinders
firing per crank revolution. However, instantaneous engine speed is
affected by two separate torque contributions. The torque resulting
from reciprocating masses in the engine, i.e., reciprocating torque, and
the torque produced by combustion pressure, i.e., gas torque. Gas
torque and reciprocating torque signals have the same frequency but
are in opposite phases. Since the resultant torque at the flywheel is the
sum of gas and reciprocating torques, there is a need to remove
reciprocating torque from the total torque at the flywheel. This requires
knowing whether gas or reciprocating torque has a larger amplitude.
Here, a method is proposed to determine whether gas or reciprocating
torque has a larger amplitude via the phase of engine speed; this
method is a step towards a practically implementable virtual torque
sensor. This methodology of torque estimation is evaluated through
on-road testing on a truck powered by a Cummins ISX12G compressed
natural gas engine at engine speeds of 1000-2100 RPM and at different
transmission gear ratios and throttle conditions. The proposed
algorithm demonstrated a mean absolute percentage error of 13.2%.
Author(s):
Nathan Ely, Vivek Iddum, Muralidhar Ghantasala, Richard T. Meyer
Affiliated:
Western Michigan University
Event:
Energy & Propulsion Conference & Exhibition
ISSN:
0148-7191
e-ISSN:
2688-3627
Related Topics:
Gas engines
Combustion and combustion processes
Transmission gears
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