Divided Exhaust Period Assessment for Fuel-Enrichment Reduction in Turbocharged Spark-Ignition Engines

IF 1.1 Q3 TRANSPORTATION SCIENCE & TECHNOLOGY
Praveen Kumar, Xin Yu, Anqi Zhang, Andrew Baur, Nayan Engineer, David Roth
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Abstract

Turbocharged spark-ignition (SI) engines, owing to frequent engine knocking events, utilize retarded spark timing that causes combustion inefficiency, and high turbine inlet temperature (Trb-In T) levels. Fuel enrichment is implemented at high power levels to prevent excessive Trb-In T levels, resulting in an additional fueling penalty and higher CO emissions. In current times, fuel-enrichment reductions are of high strategic importance for engine manufacturers to meet the imminent emissions regulations. To that end, the authors investigated the divided exhaust period (DEP) concept in a 2.2 L turbocharged SI engine with a geometric compression ratio of 14 by decoupling blowdown (BD) and scavenge (SC) events during the exhaust process. Using a validated 1D engine model, the authors first analyzed the DEP concept in terms of pumping mean effective pressure (PMEP) and engine knocking (KI) reduction. Subsequently, the authors examined the effectiveness of the DEP concept using a “low-restriction exhaust flowpath” and varying late intake valve closing (LIVC) duration.
First, using DEP, significant PMEP and KI reductions benefits were observed at high power engine conditions along with a large increase in Trb-In T from the early blowdown event. Subsequently, use of a low restriction exhaust flowpath and a shortened LIVC duration further elevated the DEP benefits, including Trb-In T reduction that facilitated enrichment reduction. At 4,000 RPM/20 bar BMEP, ~70% lower PMEP and a 2.2 point increase in ITEg were noted relative to the base engine. However, the 2,000 RPM peak torque engine condition was compromised using DEP, due to knock limitation and deteriorated stock turbocharger performance. Finally, DEP design integrated with an off-the-shelf (new) turbocharger system remedied the low-end torque challenges and demonstrated a notable enrichment reduction and thermal efficiency benefits at the full load engine curve including the 200 kW rated condition.
涡轮增压火花点火发动机燃料浓缩降低的分排气期评估
涡轮增压火花点火(SI)发动机,由于频繁的发动机爆震事件,利用延迟的火花定时,导致燃烧效率低下,高涡轮入口温度(Trb-In - T)水平。在高功率水平下进行燃料浓缩,以防止Trb-In - T水平过高,从而导致额外的加油罚款和更高的CO排放。当前,降低燃料浓缩对发动机制造商满足即将出台的排放法规具有重要的战略意义。为此,作者通过分离排气过程中的排污(BD)和扫气(SC)事件,研究了几何压缩比为14的2.2 L涡轮增压SI发动机的分排气期(DEP)概念。使用经过验证的1D发动机模型,作者首先从泵送平均有效压力(PMEP)和发动机爆震(KI)减少的角度分析了DEP概念。随后,作者使用“低限制排气流道”和不同的晚期进气阀关闭(LIVC)持续时间来检验DEP概念的有效性。首先,使用DEP,在大功率发动机条件下观察到显著的PMEP和KI降低效果,同时从早期排污事件中大幅增加Trb-In T。随后,使用低限制排气路径和缩短LIVC持续时间进一步提高了DEP效益,包括Trb-In T的减少,促进了富集的减少。在4000rpm / 20bar BMEP时,与基础发动机相比,PMEP降低了约70%,ITEg增加了2.2个点。然而,由于爆震限制和原涡轮增压器性能恶化,DEP降低了2,000 RPM峰值扭矩的发动机条件。最后,DEP设计集成了一个现成的(新型)涡轮增压器系统,解决了低端扭矩挑战,并在满载发动机曲线(包括200 kW额定工况)下显示出显著的富化降低和热效率优势。
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来源期刊
SAE International Journal of Engines
SAE International Journal of Engines TRANSPORTATION SCIENCE & TECHNOLOGY-
CiteScore
2.70
自引率
8.30%
发文量
38
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