Abstract
Opposed-piston, two-stroke engines reveal degrees of freedom that make them excellent candidates for next generation, highly efficient internal combustion engines for hybrid electric vehicles and power systems. This article reports simulation results that explore the influence of key control and geometrical parameters, specifically crankshaft phasing and intake and exhaust port height-to-stroke ratios, in obtaining best thermal efficiency. A model of a 0.75 L, single-cylinder opposed-piston two-stroke engine is exercised to predict fuel consumption as engine speed, load, crankshaft phasing, intake and exhaust port height-to-stroke ratios, and stoichiometry are varied for medium-duty truck and range extender applications. Under stoichiometric operation, optimal crankshaft phasing is seen at 0–5°, lower than reported in the literature. If stoichiometric operation is not mandated, best fuel consumption is achieved at an air-to-fuel equivalence ratio λ = 1.25 and 5–10° crankshaft phase angle, enabling a ~10 g/kWh (~4%) improvement in average brake-specific fuel consumption across medium-duty truck operating points. In range extender form, the engine provides 30 kW output power in accordance with a survey of range extender engines. In this role, there is a clear distinction between low-speed, high-load operation and vice versa. The decision as to which is more appropriate would be based on minimizing total owning and operating cost, itself a trade-off between better thermal efficiency (and thus lower fuel cost) and greater durability.
Highlights
Decarbonization of power and propulsion systems has a major role to play in mitigating anthropogenic greenhouse gas (GHG)emissions and their impact on global climate change
The aim of the present study is to explore the interrelated effects of crankshaft phasing and intake and exhaust port height-to-stroke ratios on OP2S engine performance, in order to better understand its transport decarbonization potential as a highly efficient power source for conventional or hybrid electric vehicles
An engine model is developed that correctly imitates the motion of two opposed pistons as an equivalent single piston through the use of user-defined geometrical equations
Summary
Decarbonization of power and propulsion systems (i.e., a reduction in their carbon intensity) has a major role to play in mitigating anthropogenic greenhouse gas (GHG)emissions and their impact on global climate change. Decarbonization of power and propulsion systems (i.e., a reduction in their carbon intensity) has a major role to play in mitigating anthropogenic greenhouse gas (GHG). Lowering the energy intensity of transport by enhancing vehicle and engine performance is a key factor in reducing GHG emissions and offers the potential for high levels of GHG mitigation [1]. Despite the potential of EVs to enable significant GHG reductions, their impact is hindered by the slow rate at which the fleet is replaced. This emphasizes the need to continue developing highly efficient ICEs, since they remain the incumbent propulsion technology in the near term and will exist in one form or another even beyond
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