Energy management control strategies for hybrid construction equipment: Load sharing between diesel and electric prime movers in parallel hybrid excavators
Hämtar...
Publicerad
Författare
Typ
Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Modellbyggare
Tidskriftstitel
ISSN
Volymtitel
Utgivare
Sammanfattning
This study involves the development and evaluation of energy management strategies
for hybrid excavators. A simulation-based framework was established in MATLAB
and Simulink to model a parallel-hybrid powertrain with a diesel engine and electric
motors driving the central hydraulic pump of an excavator. The load power from
the pump was split between the prime movers by controllers programmed to follow
certain strategies. Dynamic Programming (DP), Equivalent Consumption Minimi
sation Strategy (ECMS), and a rule-based approach were formulated and assessed
under varying operating conditions. The evaluation was conducted on a 50-tonne
excavator using drive cycles with high, medium, and low power demands, subject to
the operational constraints of using a smaller engine, maintaining the battery state
of charge (SoC) balance over each drive cycle, and maintaining constant hydraulic
pump speed under load.
Results indicate that a carefully designed rules-based strategy can achieve perfor
mance comparable to ECMS and the globally optimal solution indicated by the DP,
while requiring substantially lower computational requirements than the other two,
thereby enhancing its suitability for real-time implementation. Fuel consumption
reductions were observed across all cycles, with more pronounced improvements in
medium- and low-power scenarios. Combined fuel savings across all drive cycles for
the 50-tonne machine were measured at 6-8%. These learnings were further applied
to a high-power cycle of a 75-tonne excavator, with similar results. The study thus
demonstrates that a hybrid configuration comprising a smaller internal combustion
engine, supplemented by electric machines, can deliver operational capability equiv
alent to that of a larger combustion engine. This enables increased flexibility in
powertrain design, allowing manufacturers to expand machine capacity with their
existing engines.
An assessment of the total cost of ownership (TCO) was also conducted for the
50-tonne hybrid, incorporating both fuel savings and machine cost increases com
pared to the conventional machine. For this, an estimate of the required battery
size was also made. Overall, the results demonstrate that hybridisation, combined
with effective energy management strategies, can significantly enhance the efficiency,
adaptability, and economic feasibility of construction machinery.
Beskrivning
Ämne/nyckelord
hybridisation, energy management control, parallel hybrid, Total Cost of Operation, fuel savings, excavators
