柴油机的燃烧-环境优化

IF 1.3 Q2 AGRICULTURE, MULTIDISCIPLINARY
R. Pourdarbani, S. Ardabili, Ebrahim Akbarpouran, J. L. Hernández-Hernández
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引用次数: 1

摘要

摘要目前,超过一半的道路运输车队使用柴油发动机,柴油发动机通常被确定为空气污染的主要来源。此参数足以优化发动机性能和排放。发动机优化可以使用几种方法来完成,最显著的是通过修改发动机结构、使用添加剂和生物燃料改变燃料类型或实现发动机的最佳工作范围。由于需要大量的时间投入、财政资源或广泛的研究,不建议修改发动机结构并添加不同种类的材料来优化燃料。然而,实现最佳发动机性能条件的第三种方法可能是最容易获得的选择。结果表明,从多目标优化的角度来看,柴油机的最佳运行负荷约为满负荷的94–95%,表明在满负荷条件之前可以达到最佳负荷。此时,在制动比油耗为0.226 kg·kWh−1的情况下,操作员可以实现198.45 kW的制动功率和40.7%的制动热效率。在此条件下,CO2排放量为124.85 g·kWh−1,NOx排放量为7.34 g·kWh–1,CO排放量为0.6 g·kWh-1,未燃碳氢化合物排放量约为0.009 g·kWh-1,烟尘形成量约为0.0026 g·kWh。这一点等于大约35%的火用效率和大约45%的火用破坏。就终点结果而言,该条件对人类健康的影响指数为7.96E-007,0.105 PDF·m2·yr。就生态系统质量而言,就气候变化而言,为0.24千克二氧化碳当量,就资源而言,为12.96兆焦耳。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Exergo-Environmental Optimization of a Diesel Engine
Abstract Currently, more than half of the road transport fleet uses diesel engines, which are often identified as the primary source of air pollution. This parameter is enough to optimize engine performance and emissions. The engine optimization can be done using several methods, the most notably by modifying the engine structure, changing the type of fuel using additives and biofuels, or achieving the optimal operating range of the engine. Modifying the engine structure and addition of different kinds of materials to optimize fuel is not recommended either due to necessity of vast time input, financial resources, or extensive research. However, the third way to achieve optimal engine performance conditions can be the most accessible option. According to the results, the best operational load for diesel engine is approx. 94–95% of the full load from the multi-objective optimization point of view, indicating that the optimum load can be achieved before the full load condition. At this point, the operator can achieve the brake power of 198.45 kW and brake thermal efficiency of 40.7% in the presence of brake specific fuel consumption of 0.226 kg·kWh−1. At this condition, CO2 emission is 124.85 g·kWh−1, NOx emission 7.34 g·kWh−1, CO emission 0.6 g·kWh−1, unburnt hydrocarbon emission approx. 0.009 g·kWh−1, and soot formation approx. 0.006 g·kWh−1. This point is equal to the exergy efficiency of approx. 35% and the exergy destruction of approx. 45%. In terms of endpoint results, this condition achieved the impact indices of 7.96E-007 in terms of human health, 0.105 PDF·m2·yr. in terms of ecosystem quality, 0.24 kg CO2 eq. in terms of climate change, and 12.96 MJ in terms of resources.
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来源期刊
Acta Technologica Agriculturae
Acta Technologica Agriculturae AGRICULTURE, MULTIDISCIPLINARY-
CiteScore
2.50
自引率
28.60%
发文量
32
审稿时长
18 weeks
期刊介绍: Acta Technologica Agriculturae is an international scientific double-blind peer reviewed journal focused on agricultural engineering. The journal is multidisciplinary and publishes original research and review papers in engineering, agricultural and biological sciences, and materials science. Aims and Scope Areas of interest include but are not limited to: agricultural and biosystems engineering; machines and mechanization of agricultural production; information and electrical technologies; agro-product and food processing engineering; physical, chemical and biological changes in the soil caused by tillage and field traffic, soil working machinery and terramechanics; renewable energy sources and bioenergy; rural buildings; related issues from applied physics and chemistry, ecology, economy and energy.
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