不同气氛下微粒捕集器的离线再生

基于NO2、NO2/O2以及O3与PM的化学反应模型,探究了气氛对微粒捕集器（DPF）离线再生效果的影响。研究结果表明,NO2/N2的气氛下,PM的起燃温度为250℃,而在NO2/O2/N2气氛下,PM的起燃温度降至150℃左右,但在O3/N2气氛下,PM可在低于100℃的再生温度下起燃。在3种气氛下,DPF的再生效率受再生温度的影响均较为明显。当再生温度较低（≤250℃）时,O3/N2气氛下,DPF的再生效果最好,且实现完全再生的时间最短;当再生温度较高（>250℃）时,NO2/O2/N2气氛下,DPF再生效果最好,且温度越高,实现完全再生的时间越短。在所选的再生温度范围内,O3/N2气氛下的壁面最大温度梯度峰值均高于NO2/N2和NO2/O2/N2气氛,但远小于DPF安全的温度梯度极限。     

乙醇汽油与普通汽油非常规污染物排放特性对比研究

在一台满足国Ⅴ排放标准的双喷射(气口喷射+缸内直喷)汽油机上开展了燃用E10乙醇汽油(乙醇体积比为10%)对发动机非常规排放特性影响的试验研究.使用傅里叶变换红外分析仪(FTIR)测量了饱和烃、不饱和烃、芳香烃及醇、醛等非常规污染物排放量,对比分析了双喷射模式时各工况下E0和E10两种燃料的非常规排放水平.结果表明,双喷射模式下,加入乙醇有效降低了乙烯、1,3-丁二烯、苯和甲苯的排放量,但会导致乙醛排放升高.双喷射模式下,随着负荷增加,两种燃料下的1,3-丁二烯和甲苯排放呈现先升高后降低的趋势,乙烯、甲醛和苯排放则先降低后升高.乙醇能抑制1,3-丁二烯、乙烯生成,抑制效果为PFI模式优于双喷射模式,GDI模式抑制量最低.PFI和GDI模式下E10的甲醛排放均显著升高,但双喷射模式有效抑制了甲醛排放的增加.     

作业机废气减排技术研究

柴油发动机尾气排放中含有比汽油发动机更多的颗粒污染物。文章叙述了尾气净化装置反应原理,触媒及化学稳定性,柴油氧化催化剂和颗粒催化过滤器优点。通过外部加装尾气净化装置,解决了尾气污染问题,具有较好的发展前景、较强的实用性和可操作性。     

满足国五排放标准的柴油甲醇双燃料发动机非常规排放研究

在一台装备有电控单体泵增压中冷系统柴油机的进气管上,加装甲醇喷射装置并向进气道喷入定量的纯甲醇,结合废气再循环(EGR)技术并使用氧化催化转化器(DOC)组合微粒氧化催化器(POC)后处理系统,使其常规排放能满足国五排放法规基础上,全面研究了柴油甲醇双燃料(Diesel Methanol Dual Fuel,DMDF)发动机的非常规排放特性.在采用国五排放法规标准规定的ESC(稳态13点工况)测试方法条件下,利用FTIR(傅里叶变换红外检测法)对DMDF发动机的检测结果表明:该机非常规排放物主要为甲醇、甲醛、1,3-丁二烯、苯、甲苯和SO2,非常规排放物的全工况加权比排放为19.532 g·kW~(-1)·h~(-1),其中,甲醇的全工况加权比排放为11.395 g·kW~(-1)·h~(-1),甲醛的全工况加权比排放为5.927g·kW~(-1)·h~(-1),SO2的全工况加权比排放为0.053 g·kW~(-1)·h~(-1),其余排放物为痕量水平.在催化氧化装置处理后非常规排放物全工况加权比排放为0.115 g·kW~(-1)·h~(-1),降幅为99.41%.催化氧化装置对甲醇、1,3-丁二烯、苯和甲苯的消除率为100%,对甲醛的消除率为99.04%.     

新型射汽抽气消声器

介绍了一种自行设计的、新型的汽轮机启动抽气器排汽消声装置，并对其结构原理和设计特点进行了较详细的叙述。应用实践表明，此种消声器降噪效果明显。     

航空发动机涡轮叶片热障涂层冲蚀试验装置的研制

目的通过研制热障涂层冲蚀服役环境的模拟装置,来研究冲蚀失效机制。方法通过研制模拟热障涂层高温热冲击的燃气喷枪,在喷枪中设计速度、流量可控的颗粒送料系统,同时在装置中集成裂纹演化实时检测的声发射系统。结果该系统实现了热障涂层冲蚀服役环境的模拟,温度场、裂纹演化损伤参量的同步采集、输出与显示,从而完成了冲蚀服役环境模拟与关键损伤参量实时检测的一体化设计。结论装置能完成热障涂层常温、高温等各种服役温度、各种冲蚀角度、各种冲蚀速度等条件下的模拟试验,并提供较为系统的损伤参量检测数据,为理解热障涂层的冲蚀机理、优化其设计制备提供有效的试验数据。     

Efforts to Reduce Mortality to Hydroelectric Turbine-Passed Fish: Locating and Quantifying Damaging Shear Stresses

Severe fluid forces are believed to be a source of injury and mortality to fish that pass through hydroelectric turbines. A process is described by which laboratory bioassays, computational fluid dynamics models, and field studies can be integrated to evaluate the significance of fluid shear stresses that occur in a turbine. Areas containing potentially lethal shear stresses were identified near the stay vanes and wicket gates, runner, and in the draft tube of a large Kaplan turbine. However, under typical operating conditions, computational models estimated that these dangerous areas comprise less than 2% of the flow path through the modeled turbine. The predicted volumes of the damaging shear stress zones did not correlate well with observed fish mortality at a field installation of this turbine, which ranged from less than 1% to nearly 12%. Possible reasons for the poor correlation are discussed. Computational modeling is necessary to develop an understanding of the role of particular fish injury mechanisms, to compare their effects with those of other sources of injury, and to minimize the trial and error previously needed to mitigate those effects. The process we describe is being used to modify the design of hydroelectric turbines to improve fish passage survival.     

Regulated and unregulated emissions from a diesel engine fueled with biodiesel and biodiesel blended with methanol

Experiments were carried out on a diesel engine operating on Euro V diesel fuel, pure biodiesel and biodiesel blended with methanol. The blended fuels contain 5%, 10% and 15% by volume of methanol. Experiments were conducted under five engine loads at a steady speed of 1800 rev min⁻¹ to assess the performance and the emissions of the engine associated with the application of the different fuels. The results indicate an increase of brake specific fuel consumption and brake thermal efficiency when the diesel engine was operated with biodiesel and the blended fuels, compared with the diesel fuel. The blended fuels could lead to higher CO and HC emissions than biodiesel, higher CO emission but lower HC emission than the diesel fuel. There are simultaneous reductions of NO_x and PM to a level below those of the diesel fuel. Regarding the unregulated emissions, compared with the diesel fuel, the blended fuels generate higher formaldehyde, acetaldehyde and unburned methanol emissions, lower 1,3-butadiene and benzene emissions, while the toluene and xylene emissions not significantly different.     

柴油机排放颗粒物组成分析

采用过滤分离、超声洗脱和气质联用等技术,实验测定了柴油机尾气中碳烟颗粒物的质量含量、可溶性有机组分在颗粒物中的质量分数和可溶性有机组分的化学组成。在实验条件下,柴油机尾气中碳烟颗粒物的质量含量为32·6~143·6mg/m3。可溶性有机组分在颗粒物中的质量分数为18·5%~89·4%。可溶性有机组分中检测出有机物100多种,已确定化学结构的有机物73种,其中直链和支链烷烃含量占81·22%,芳烃类化合物17·94%。     

Emission and Performance Characteristics of a 2 Litre Toyota Diesel Van Operating on Esterified Waste Cooking Oil and Mineral Diesel Fuel

Exhaust emission and performance characteristics were evaluated in a Toyota van, powered by a 21 indirect injection (IDI) naturally aspirated diesel engine, operating on vegetable based waste cooking oil methyl ester (WCOME).Tests were performed on a chassis dynamometer and the data were compared with previous results conducted on the same vehicle using mineral diesel fuel. The data obtained includes smoke opacity, carbon monoxide (CO), carbon dioxide (CO₂), oxygen (O₂), nitrogen dioxide (NO₂), nitric oxide (NO), sulfur dioxide (SO₂) and brake power. Engine lubricating oil samples were also taken. Results from this study indicated a difference of approximately 9% in brake power between the two fuels. WCOME developed a significant lower smoke opacity level and reduced CO, CO₂, SO₂ emissions. However, O₂, NO₂ and NO levels were higher with the vegetable oil based fuel. Power values were comparable for both fuels. Lubricating oil analysis gave little change of viscosity and wear metal concentrations after 2887km were: Silicon 35ppm, Chromium 3.3ppm, Iron 33.8ppm, Copper 14.1ppm and lead 78.6ppm.