Assessing the potential and energy distribution calibration of ethanol-biodiesel based RCCI mode of compression ignition engine in a plugin parallel hybrid electric vehicle

Rajasekar Vignesh, David Ray George, Bragadeshwaran Ashok, Vijayakumar Thulasi, Dariusz Szpica
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Abstract

The focus of this research is to develop the resilient powertrain to combat the enforcement of stringent emission regulations and elevate its feasibility to power with the sustainable fuels to support the fuel crisis. The current solution in the reliable and adaptability point of view is the low temperature combustion engine-based hybrid electric powertrain powered with sustainable fuel is the better choice. The present work proposes the concept of an ethanol-biodiesel fuel based RCCI plugin parallel hybrid electric vehicles (PHEVs). The significant examination of this work in the aspects of optimal torque structure and injector control parameter calibration. The calibration of the RCCI engine torque structure operation is performed based on the multi-objective constraints of variance of indicated mean effective pressure and the maximum rate of pressure rise for the combustion stability. While the equivalence ratio and combustion temperature with emphasis on limiting the amount of NOx and soot emissions. The maximum ethanol energy share proportion of 66.98% has been achieved. The RCCI engine is most frequently operating in the torque zone of 10 Nm and then 17.81 Nm while the BLDC motor is most frequently operated in the range of 55 Nm even at max torque of 60 Nm. When comparing to a standard diesel hybrid setup, the ethanol-biodiesel fuelled RCCI setup has a 18%–19% reduction in harmful NOx emissions, with an equivalent decrease of 22.7% in fuel economy. This is achieved by only having a 13.4% more CO emission while a minimal increase in soot emission throughout the overall course of the driving cycle. The result of this work shows evidence that implementing an ethanol-biodiesel fuelled RCCI engine in a parallel hybrid configuration achieves a significant reduction in NOx emissions while achieving the performance targets and managing the fuel and battery energy utilization over a driving cycle efficiently.
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评估插电式并联混合动力电动汽车中基于乙醇-生物柴油的 RCCI 模式压燃发动机的潜力和能量分布校准
这项研究的重点是开发弹性动力系统,以应对严格的排放法规,并提高其使用可持续燃料的可行性,以应对燃料危机。从可靠性和适应性的角度来看,目前的解决方案是以低温内燃机为基础、以可持续燃料为动力的混合动力系统是更好的选择。本作品提出了基于乙醇-生物柴油燃料的 RCCI 插电式并联混合动力电动汽车(PHEV)的概念。这项工作在优化扭矩结构和喷油器控制参数校准方面进行了重要研究。RCCI 发动机扭矩结构操作的标定是基于指示平均有效压力方差和燃烧稳定性最大压力上升率的多目标约束。而当量比和燃烧温度则侧重于限制氮氧化物和烟尘的排放量。乙醇的最大能量份额比例达到了 66.98%。RCCI 发动机最常在 10 牛米和 17.81 牛米的扭矩范围内工作,而无刷直流电机最常在 55 牛米的范围内工作,甚至在最大扭矩为 60 牛米时也是如此。与标准柴油混合动力系统相比,以乙醇-生物柴油为燃料的 RCCI 系统的有害氮氧化物排放量减少了 18%-19%,而燃油经济性则降低了 22.7%。在整个驾驶循环过程中,二氧化碳排放量只增加了 13.4%,而烟尘排放量的增加却微乎其微。这项工作的结果表明,在并联混合动力配置中采用乙醇-生物柴油燃料 RCCI 发动机可显著减少氮氧化物排放,同时实现性能目标,并在整个驾驶周期中有效管理燃料和电池能量的利用。
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来源期刊
CiteScore
3.80
自引率
10.00%
发文量
625
审稿时长
4.3 months
期刊介绍: The Journal of Mechanical Engineering Science advances the understanding of both the fundamentals of engineering science and its application to the solution of challenges and problems in engineering.
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