重型非公路物料搬运车的推进电气化结构选择过程和碳减排成本分析

IF 0.6 Q4 TRANSPORTATION SCIENCE & TECHNOLOGY
Bryant Goodenough, Alexander Czarnecki, Darrell Robinette, Jeremy Worm, Brian Burroughs, Phil Latendresse, John Westman
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引用次数: 0

摘要

重型非公路车辆行业继续加大力度降低油耗和 CO2e(二氧化碳当量)排放。许多制造商正在追求电气化,以降低油耗和排放。正如轻型公路车辆一样,未来的政策很可能要求电气化以减少 CO2e 排放。在重型非公路车辆领域,电气化结构差异很大,有些应用采用并联式混合动力,有些则采用串联式混合动力。不同类型设备的不同应用意味着需要不同的电气化配置。公司还必须确定采用电气化架构的价值;这项工作分析了一系列电气化架构,从微型混合动力到并联式混合动力到串联式混合动力再到 BEV,并使用 2021 年的数据研究了总成本、总 CO2e 和每 CO2e 成本(碳减排成本或减碳成本)。这项研究的重点是重型非公路物料搬运车,即 Pettibone Cary-Lift 204i。由于该设备的特殊用途,包括从轨道车上卸载大型油管等,因此需要一种适合其特殊需求的独特电气化结构。不过,这项研究的结果可以推广到类似的机械上,为整个重型非公路机械行业的节油方案提供参考。本研究为 Cary-Lift 确定了独特的电气化结构。该架构通过多轮普格矩阵决策分析来选择理想的电气化架构精简列表。对精简列表进行建模和模拟,以确定二氧化碳当量、成本和每二氧化碳当量成本。最终确定的架构为插电式串联混合动力车,可降低 65% 的燃油消耗,目标是节省大量燃油和 CO2e,这可能是未来重型越野车行业的要求。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Propulsion Electrification Architecture Selection Process and Cost of Carbon Abatement Analysis for Heavy-Duty Off-Road Material Handler
The heavy-duty off-road industry continues to expand efforts to reduce fuel consumption and CO2e (carbon dioxide equivalent) emissions. Many manufacturers are pursuing electrification to decrease fuel consumption and emissions. Future policies will likely require electrification for CO2e savings, as seen in light-duty on-road vehicles. Electrified architectures vary widely in the heavy-duty off-road space, with parallel hybrids in some applications and series hybrids in others. The diverse applications for different types of equipment mean different electrified configurations are required. Companies must also determine the value in pursuing electrified architectures; this work analyzes a range of electrified architectures, from micro hybrids to parallel hybrids to series hybrids to a BEV, looking at the total cost, total CO2e, and cost per CO2e (cost of carbon abatement, or cost of carbon reduction) using data for the year 2021. This study is focused on a heavy-duty off-road material handler, the Pettibone Cary-Lift 204i. This machine’s specialty application, including events like unloading large oil pipes from a railcar, requires a unique electrified architecture that suits its specific needs. However, the results from this study may be extrapolated to similar machinery to inform fuel savings options across the heavy-duty off-road industry. In this study, a unique electrified architecture is determined for the Cary-Lift. This architecture is informed by multiple rounds of a Pugh matrix decision analysis to select a shortened list of desirable electrified architectures. The shortened list is modeled and simulated to determine CO2e, cost, and cost per CO2e. A final architecture is determined as a plug-in series hybrid that reduces fuel consumption by 65%, targeting the large fuel and CO2e savings that are likely to be required for the future of the heavy-duty off-road industry.
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来源期刊
SAE International Journal of Commercial Vehicles
SAE International Journal of Commercial Vehicles TRANSPORTATION SCIENCE & TECHNOLOGY-
CiteScore
1.80
自引率
0.00%
发文量
25
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