The simulation based investigation of the variable displacement engine is motivated by a desire to enable unthrottled operation at part load, and hence eliminate pumping losses. The mechanism modeled in this work is derived from a Hefley engine concept. Other salient features of the proposed engine are turbocharging and cylinder deactivation. The cylinder deactivation combined with variable displacement further expands the range of unthrottled operation, whereas turbocharging increases the power density of the engine and allows downsizing without the loss of performance. Although the proposed variable displacement turbocharged engine (VDTCE) concept enables operations in a very wide range, running near idle is impractical. Therefore, the VDTCE is integrated with a hybrid powertrain to mitigate issues with engine transients and mode transitions. The engine model is developed in AMESim using physics based models, such as thermodynamic cycle simulation, filling and emptying of manifolds, and turbulent flame entrainment combustion. A predictive model of the power-split hydraulic hybrid driveline is created in SIMULINK, thus facilitating integration with the engine. The integrated simulation tool is utilized to address design and control issues, before determining the fuel economy potential of the powertrain comprising a VDTCE engine and a hydraulic hybrid driveline.
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December 2011
Research Papers
Simulation Study of Advanced Variable Displacement Engine Coupled to Power-Split Hydraulic Hybrid Powertrain
Zoran Filipi
Zoran Filipi
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Zoran Filipi
J. Eng. Gas Turbines Power. Dec 2011, 133(12): 122803 (12 pages)
Published Online: August 31, 2011
Article history
Received:
May 4, 2010
Revised:
March 17, 2011
Published:
August 31, 2011
Citation
Tavares, F., Johri, R., and Filipi, Z. (August 31, 2011). "Simulation Study of Advanced Variable Displacement Engine Coupled to Power-Split Hydraulic Hybrid Powertrain." ASME. J. Eng. Gas Turbines Power. December 2011; 133(12): 122803. https://doi.org/10.1115/1.4004073
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