The effects of pilot injection timing on the combustion process and exhaust emissions in dual-fuel diesel engine using biodiesel-CNG at high load

THE 4TH BIOMEDICAL ENGINEERING’S RECENT PROGRESS IN BIOMATERIALS, DRUGS DEVELOPMENT, HEALTH, AND MEDICAL DEVICES: Proceedings of the International Symposium of Biomedical Engineering (ISBE) 2019 Pub Date : 2019-12-10 DOI:10.1063/1.5138286

A. Trihatmojo, Dori Yuvenda, B. Sudarmanta

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引用次数: 4

Abstract

Biodiesel and compressed natural gas (CNG) are alternative fuels that can be used in the dual-fuel engine. In this research, Biodiesel was used as a combustion pilot and CNG was applied as a substitution fuel injected at the intake process. The pilot injection timing has an important role in controlling the initial combustion of dual-fuel combustion. It is caused by the ignition delay of dual-fuel engines longer than single-fuel engines. The engine was kept at a constant speed of 2000 rpm and was given a high load. The single fuel mode used standard injection time of -13 °CA ATDC. The time of pilot injection in the dual-fuel engine was varied from -11 to -19 °CA ATDC in steps of -2 °CA to investigate the combustion process and exhaust emissions. The results show that dual-fuel mode with the standard time of pilot injection produces the cylinder pressure and heat release rate (HRR) greater than the single-fuel mode. Moreover, cylinder pressure increases 21.46% and peak pressure in the range of 10 – 15 °CA ATDC with advanced the time of pilot injection in dual-fuel mode. However, HRR slightly increases by 4.79% at high load. The lower exhaust emissions can be achieved with advanced the time of pilot injection -17° CA ATDC at high load.Biodiesel and compressed natural gas (CNG) are alternative fuels that can be used in the dual-fuel engine. In this research, Biodiesel was used as a combustion pilot and CNG was applied as a substitution fuel injected at the intake process. The pilot injection timing has an important role in controlling the initial combustion of dual-fuel combustion. It is caused by the ignition delay of dual-fuel engines longer than single-fuel engines. The engine was kept at a constant speed of 2000 rpm and was given a high load. The single fuel mode used standard injection time of -13 °CA ATDC. The time of pilot injection in the dual-fuel engine was varied from -11 to -19 °CA ATDC in steps of -2 °CA to investigate the combustion process and exhaust emissions. The results show that dual-fuel mode with the standard time of pilot injection produces the cylinder pressure and heat release rate (HRR) greater than the single-fuel mode. Moreover, cylinder pressure increases 21.46% and peak pressure in the range of 10 – 15 °CA ...

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中试喷油时机对生物柴油-压缩天然气双燃料发动机高负荷燃烧过程及废气排放的影响

生物柴油和压缩天然气(CNG)是可用于双燃料发动机的替代燃料。在本研究中，生物柴油作为燃烧先导，CNG作为替代燃料注入进气过程。在双燃料燃烧过程中，先导喷射正时对控制初始燃烧具有重要作用。这是由于双燃料发动机的点火延迟时间比单燃料发动机长。发动机保持在每分钟2000转的恒定转速，并被赋予高负荷。单燃料模式采用-13°CA ATDC标准喷射时间。在-11°CA至-19°CA的ATDC范围内，双燃料发动机的先导喷射时间在-2°CA的步骤中变化，以研究燃烧过程和废气排放。结果表明，双燃料模式下，驾驶员喷射标准时间下的气缸压力和热释放率(HRR)大于单燃料模式。双燃料模式下，随着先导喷射时间的提前，缸压和峰值压力在10 ~ 15°CA ATDC范围内提高了21.46%。然而，在高负载下，HRR略微增加了4.79%。在高负荷工况下，提前先导喷射时间(-17°CA ATDC)可实现较低的尾气排放。生物柴油和压缩天然气(CNG)是可用于双燃料发动机的替代燃料。在本研究中，生物柴油作为燃烧先导，CNG作为替代燃料注入进气过程。在双燃料燃烧过程中，先导喷射正时对控制初始燃烧具有重要作用。这是由于双燃料发动机的点火延迟时间比单燃料发动机长。发动机保持在每分钟2000转的恒定转速，并被赋予高负荷。单燃料模式采用-13°CA ATDC标准喷射时间。在-11°CA至-19°CA的ATDC范围内，双燃料发动机的先导喷射时间在-2°CA的步骤中变化，以研究燃烧过程和废气排放。结果表明，双燃料模式下，驾驶员喷射标准时间下的气缸压力和热释放率(HRR)大于单燃料模式。在10 ~ 15°CA范围内，气缸压力增加了21.46%，峰值压力增加了21.46%。

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THE 4TH BIOMEDICAL ENGINEERING’S RECENT PROGRESS IN BIOMATERIALS, DRUGS DEVELOPMENT, HEALTH, AND MEDICAL DEVICES: Proceedings of the International Symposium of Biomedical Engineering (ISBE) 2019

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