Modeling and Control of a Hybrid Opposed Piston Engine

Drallmeier, Joseph A.; Siegel, Jason B.; Middleton, Richard H.; Stefanopoulou, Anna G.; Salvi, Ashwin; Huo, Ming

doi:10.1115/icef2021-67541

Cited by 5 publications

(14 citation statements)

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“…The resulting finite dimensional optimization problem is solved using IPOPT. 23 The system dynamics referred to in equation (4a), fully defined in the Appendix A, are a simplified version of the modeling described in the high-fidelity model presented previously 21 in regards to the coupling between engine crankshaft and motor as well as the open cycle breathing and thermodynamic models. However, despite this simplification, discrete changes are still present in the system dynamics due to the intake and exhaust port actuation, fuel injection, and the combustion process.…”

Section: Numerical Optimization Setupmentioning

confidence: 99%

“…A description of the high-fidelity co-simulation an be found in elsewhere. 21 Iterations between the high-fidelity modeling and the optimization process are repeated until the pressure and temperature of the high-fidelity model at the port closing event are within 0.01 bar and 0.1 K, respectively, of the previous iteration values. Further, the peak cylinder pressure in the optimization model must be within 0.1 bar of the previous cycle, showing convergence of the optimization process.…”

Section: Optimal Control Problemmentioning

confidence: 99%

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Optimizing the fuel efficiency of an opposed piston engine for electric power generation

Drallmeier

Middleton

Siegel

2022

International Journal of Engine Research

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This paper investigates the optimal crankshaft motion for an opposed piston (OP) engine in a novel hybrid architecture to maximize fuel efficiency. The OP engine was selected for this work due to its inherent thermodynamic benefits and the balanced nature of the engine which can achieve downsizing through reducing the number of cylinders rather than the individual cylinder volume. The typical geartrain required on an OP engine was exchanged for two electric motors, reducing friction loss and decoupling the crankshafts. Using the motors to control the crankshaft motion profiles, this architecture introduces capabilities to dynamically vary compression ratio, combustion volume, and scavenging dynamics. To leverage these opportunities, an optimization scheme was developed utilizing nonlinear optimization of a 0-D model to compute the crankshaft motion profile that maximizes the work generated by the system. This optimization was then iteratively coupled with a high fidelity model which supplies the cylinder flow boundary conditions. This iterative approach reduces the model complexity used in the optimal control problem (OCP) while capturing the gas exchange dynamics critical to the 2-stroke cycle of the OP engine. By using the rate of change of motor torque as the input to the OCP, the torque fluctuation in a single cycle can be limited to ensure tracking feasibility. The results show crankshaft velocity slows during the compression stroke and conversely accelerates during the expansion stroke, reducing the peak motor torque required for control and thus reducing the motor losses. The extended residence time at top dead center, however, leads to an increase in heat transfer, illustrating the trade-off between the work extraction efficiency and the indicated engine efficiency.

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Section: Numerical Optimization Setupmentioning

confidence: 99%

Section: Optimal Control Problemmentioning

confidence: 99%

Optimizing the fuel efficiency of an opposed piston engine for electric power generation

Drallmeier

Middleton

Siegel

2022

International Journal of Engine Research

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“…The port width only affects the area of the intake and exhaust ports; the port height not only affects the port area but also affects the intake and exhaust phases. 17–19 The port inclination contains radial inclination and axial inclination. The radial inclination generates a swirling flow, 20,21 while the axial inclination angle creates a tumbling flow.…”

Section: Identification Of the Factors Influencing Intake/exhaust Timesmentioning

confidence: 99%

Identification and analysis of the factors to realizing variable intake/exhaust phases in opposed-piston two-stroke diesel engines

Yang

et al. 2022

Advances in Mechanical Engineering

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The opposed-piston, two-stroke (OP2S) diesel engine is a potential power system to promote thermal efficiency, but the engine has an inferior scavenging performance. Through variable intake/exhaust times, the combustion process can be effectively facilitated. For example, the VVT technology is used in traditional engines. However, this technology has not been applied to OP2S diesel engines. This present work analyzed parameters influencing the intake/exhaust times to find a way to realize variable intake/exhaust times in OP2S diesel engines. These parameters affecting intake/exhaust times were mainly focused on, for example, crank to link ratio (CLR), piston phase difference (PPD), and port height (PH). Through investigating their influence on IMEP, scavenging efficiency, and trapping efficiency, we evaluated the different schemes from performance, intake/exhaust phases, and realization cost. The results show that the PH scheme significantly precedes the PPD and CLR schemes for realizing the variable intake/exhaust times. The PH scheme owns a more extensive phase adjustment range of 31°CA, the IMEP of 0.75 MPa, and the scavenging efficiency of 0.74. To achieve better power and scavenging performance, the EPH should be 37.5% higher than IPH, and the PPD should be kept below 15°CA.

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“…Resultantly, there has been a resurgence of interest in automotive two-stroke engine research in recent times. 8,11–17…”

Section: Introductionmentioning

confidence: 99%

“…The computed TER and temporal insights gained regarding the flow physics of scavenging will be used to develop improved simple gas-exchange models that are less reliant on engine/operating-condition-specific empirical tuning, as is the case for currently available models, 18–22 and are more phenomenological in nature. Such models will help develop robust and flexible control systems for managing engine operation across an increasingly wide-ranging list of control variables, for example, fuel composition variations, 23 variable valve/port opening timing, 12,16 variable compression ratio, 8 multiple injections. 11,17 Moreover, such phenomenological models can be integrated into thermodynamic 1D engine models to help in the engine design and development stages.…”

Section: Introductionmentioning

confidence: 99%

Trapped equivalence ratio determination in two-stroke engines

Bajwa

Patterson

Jacobs

2022

Proceedings of the Institution of Mechanical Engineers, Part D:

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The chemical composition of the trapped fuel-air-residual gas mixture controls the nature of combustion in internal combustion engines and thus serves as a key determinant of the ensuing emissions and work production processes. A frequently used trapped composition metric for engine control is the trapped equivalence ratio. Unfortunately, in two-stroke engines, it is unfeasible to accurately determine this using traditional intake flow and exhaust emissions measurements because of the simultaneous occurrence of intake and exhaust processes, which causes: (1) exhaust emissions to be diluted by the slippage (short-circuiting) of fresh air through the exhaust ports, i.e., trapping inefficiencies, and (2) high residual combustion product retainment, i.e., scavenging inefficiencies. The current paper supplements scavenging efficiency data obtained in a previous study for a cross-scavenged, natural-gas, two-stroke engine with experimental trapping efficiency data from the same engine, and characterizes the overall gas-exchange (scavenging + trapping) behavior of the engine at two engine loads, three speeds, and three spark timings. The trapping efficiency experiments use natural gas as a tracer for fresh charge and the total gas-exchange data is used to compute the trapped equivalence ratio. The trapping performance of the engine – which improves with speed and load increase, and spark retardation – along with scavenging, volumetric, thermal, and combustion efficiency changes determine the trapped equivalence ratio of the engine. The relationship between trapped equivalence ratio and NOx emissions is presented and the importance of accounting for scavenging and trapping inefficiencies in accurately determining equivalence ratio is discussed.

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Modeling and Control of a Hybrid Opposed Piston Engine

Cited by 5 publications

References 0 publications

Optimizing the fuel efficiency of an opposed piston engine for electric power generation

Optimizing the fuel efficiency of an opposed piston engine for electric power generation

Identification and analysis of the factors to realizing variable intake/exhaust phases in opposed-piston two-stroke diesel engines

Trapped equivalence ratio determination in two-stroke engines

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