Impact of cylinder deactivation on fuel efficiency in off-road heavy-duty diesel engines during high engine speed operation

IF 6.1 2区 工程技术 Q2 ENERGY & FUELS Applied Thermal Engineering Pub Date : 2024-09-10 DOI:10.1016/j.applthermaleng.2024.124333
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Abstract

Off-road heavy-duty diesel engines are equipped with complex aftertreatment systems to meet the stringent EPA Tier 4 emission standards. Traditionally, the thermal management of the aftertreatment system, aimed at efficiently reducing tailpipe emissions, involves controlling engine exhaust flow and temperature. However, this approach often leads to inefficient engine operation, especially in the low to mid-load regions, resulting in higher fuel consumption. Prior studies have highlighted the potential of cylinder deactivation (CDA) in reducing fuel consumption and increasing the exhaust temperature for thermal management in on-road applications. As the significance of controlling greenhouse gas (GHG) emissions from off-road machinery comes into focus, this study aims to experimentally demonstrate the fuel efficiency benefits and efficient aftertreatment thermal management achieved through CDA during high-speed operation on a Tier 4 level off-road heavy-duty diesel engine. In a typical off-road duty cycle, such as Non-Road Transient Cycle (NRTC), about 82.5% of cycle’s energy is produced in the engine speed range of 1750–2200 rpm, prompting investigation into the impact of CDA during high-speed operations. CDA results in airflow reductions and increased exhaust gas temperatures due to lower air–fuel ratio (AFR). The reduced airflow operation minimizes pumping work, allowing for higher open cycle efficiency, and thereby translating into lower fuel consumption. The study reveals a new finding: fuel benefits from CDA extend over a larger load range (up to 8.3 bar BMEP) during high-speed operation in off-road heavy-duty engines compared to findings in on-road heavy-duty engines. This phenomenon can be attributed to sufficient oxygen inducted during CDA operation, resulting from similar turbocharger speeds compared to all-cylinder firing operation, especially at high-loads, thereby maintaining particulate matter (PM) concentration within prescribed constraints. Steady-state test results demonstrate a reduction in fuel consumption from 33.7% at 0.4 bar to 1.4% at 8.3 bar BMEP, at 2100 rpm engine speed.

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发动机高速运转时气缸停用对非公路重型柴油发动机燃油效率的影响
非公路重型柴油发动机配备了复杂的后处理系统,以满足严格的美国环保署 Tier 4 排放标准。传统上,后处理系统的热管理旨在有效减少尾气排放,包括控制发动机排气流量和温度。然而,这种方法往往会导致发动机运行效率低下,尤其是在中低负荷区域,从而导致油耗升高。先前的研究强调了气缸停用(CDA)在降低油耗和提高排气温度方面的潜力,以便在公路应用中进行热管理。随着控制非道路机械温室气体(GHG)排放的重要性成为关注焦点,本研究旨在通过实验证明,在一台 4 级非道路重型柴油发动机高速运行期间,通过 CDA 实现的燃油效率优势和高效的后处理热管理。在典型的非道路工作循环(如非道路瞬态循环(NRTC))中,约 82.5% 的循环能量是在发动机转速为 1750-2200 rpm 的范围内产生的,这促使我们研究 CDA 在高速运行时的影响。由于空燃比(AFR)降低,CDA 导致气流减少和废气温度升高。气流减小后,泵功最小化,开式循环效率更高,因此油耗更低。该研究揭示了一个新发现:与公路重型发动机的研究结果相比,在非公路重型发动机高速运行期间,CDA 的燃油效益可扩展到更大的负荷范围(最高达 8.3 巴 BMEP)。这一现象可归因于在 CDA 运行期间,由于涡轮增压器的转速与全缸点火运行的转速相近,从而产生了充足的氧气,特别是在高负荷时,从而将颗粒物质 (PM) 的浓度保持在规定的限制范围内。稳态测试结果表明,在发动机转速为 2100 rpm 时,油耗从 0.4 巴时的 33.7% 降至 8.3 巴 BMEP 时的 1.4%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Applied Thermal Engineering
Applied Thermal Engineering 工程技术-工程:机械
CiteScore
11.30
自引率
15.60%
发文量
1474
审稿时长
57 days
期刊介绍: Applied Thermal Engineering disseminates novel research related to the design, development and demonstration of components, devices, equipment, technologies and systems involving thermal processes for the production, storage, utilization and conservation of energy, with a focus on engineering application. The journal publishes high-quality and high-impact Original Research Articles, Review Articles, Short Communications and Letters to the Editor on cutting-edge innovations in research, and recent advances or issues of interest to the thermal engineering community.
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