Study of Pulsed Plasma in a Crossed Flow Dielectric Barrier Discharge Reactor for Improvement of NO_x Removal in Raw Diesel Engine Exhaust

Improved performance of plasma in raw engine exhaust treatment is reported. A new type of reactor referred to as of cross-flow dielectric barrier discharge （DBD） was used, in which the gas flow is perpendicular to the corona electrode. In raw exhaust environment, the cross-flow （radial-flow） reactor exhibits a superior performance with regard to NOx removal when compared to that with axial flow of gas. Experiments were conducted at different flow rates ranging from 2 L/min to 25 L/min. The plasma assisted barrier discharge reactor has shown encouraging results in NOx removal at high flow rates.

Removal of Nitrogen Oxides in Diesel Engine Exhaust by Plasma Assisted Molecular Sieves

This paper reports the studies conducted on removal of oxides ofnitrogen (NOx) from diesel engine exhaust using electrical dischargeplasma combined with adsorbing materials such as molecular sieves.This study is being reported for the first time. The exhaust is takenfrom a diesel engine of 6 kW under no load conditions. Thecharacteristic behavior of a pulse energized dielectric barrierdischarge reactor in the diesel exhaust treatment is reported. TheNOx removal was not significant (36/100) when the reactor without anypacking was used.

Design and Experiment for Exhaust Pipes of Pressure Wave Supercharged Diesel Engine

NOx and soot emissions from diesel engines can be greatly reduced by pressure wave supercharging(PWS).The diesel engine matched with PWS needs redesigning its exhaust pipes.Except for meeting the installation requirements,the exhaust gas must be stable in pressure before rushing into PWS.In this paper the lateral and center ported divergent exhaust pipes are designed,modeled geometrically and analyzed structurally based on a 3-D design software-CATIA to determine the structure of two exhaust pipes having the required inner volume.Then flow analysis for two exhaust pipes is done using a flow analysis software-ANASYS.Moreover,the optimal exhaust pipes are determined comprehensively and cast for engine test.Engine test results show that PWS is superior to turbocharging at low engine speeds and inferior to turbocharging in power and emissions at medium-to-high engine speeds.The performance of PWS engine under high speed operating conditions can be improved by contriving larger surge volume intake and exhaust pipes.

Raman spectroscopy of diesel and gasoline engine-out soot using different laser power

We studied engine-out soot samples collected from a heavy-duty direct-injection diesel engine and port-fuel injection gasoline spark-ignition engine. The two types of soot samples were characterized using Raman spectroscopy with different laser powers. A Matlab program using least-square-method with trust-region-reflective algorithm was developed for curve fitting. A DOE(design of experiments) method was used to avoid local convergence. The method was used for two-band fitting and three-band fitting. The fitting results were used to determine the intensity ratio of D(for "Defect" or "Disorder") and G(for"Graphite") Raman bands. It is found that high laser power may cause oxidation of soot sample, which gives higher D/G intensity ratio. Diesel soot has consistently higher amorphous/graphitic carbon ratio, and thus higher oxidation reactivity, compared to gasoline soot, which is reflected by the higher D/G intensity ratio in Raman spectra measured under the same laser power.

Engineering property test of kaolin clay contaminated by diesel oil

Engineering property of kaolin clay contaminated by diesel oil was studied through a series of laboratory experiments.Oil contents(mass fraction) of 4%,8%,12%,16% and 20% were selected to represent different contamination degrees,and the soil specimens were manually prepared through mixing and static compaction method.Initial water content and dry density of the test kaolin clay were controlled at 10% and 1.58 g/cm^3,respectively.Test results indicate that since part of the diesel oil will be released from soil by evaporation,the real water content should be derived through calibration of the quasi water content obtained by traditional test method.As contamination degree of the kaolin clay increases,both liquid limit and plastic limit decrease,but there's only a slight increase for plasticity index.Swelling pressure of contaminated kaolin clay under confined condition will be lowered when oil-content gets higher.Unconfined compressive strength(UCS) of the oil-contaminated kaolin clay is influenced by not only oil content but also curing period.Increase of contamination degree will continually lower UCS of the kaolin clay specimen.In addition,electrical resistivity of the contaminated kaolin clay with given water content decreases with the increase of oil content.However,soil resistivity is in good relationship with oil content and UCS.Finally,oil content of 8% is found to be a critical value for engineering property of kaolin clay to transit from water-dominated towards oil-dominated characteristics.

The zero-dimensional model of the scavenging process in the opposed-piston two-stroke aircraft diesel engine

The analysis of the scavenging process in two-stroke engines is important in terms of achieved performance and emission of toxic substances.The amount of mass of air used for the scavenging process and the amount mass of gas retained in the cylinder affect engine effi-ciency.When designing two-stroke engines,the most efficient charge exchange process defined by the scavenging efficiency parameter is desirable.The process of charge exchange in a twostroke opposed-piston aircraft diesel engine based on the assumed scavenging model was analyzed in this work.The charge exchange process was performed by a mechanical centrifugal compressor.A zero-dimensional engine model created in the AVL BOOST program was used for the research.The simulation tests were performed for the selected operating conditions,i.e.maximum continuous power.The analysis of the charge exchange process was accompanied by obtaining the basic engine operating parameters from the simulation calculations.

Development of Fuel/Engine Systems—The Way Forward to Sustainable Transport

The global demand for transport energy is large, growing, and primarily met by petroleum-derived liquid fuels powering internal combustion engines (ICEs). Moreover, the demand for jet fuel and diesel is projected to grow faster than the demand for gasoline in the future, and is likely to result in low-octane gasoline components becoming more readily available. Significant initiatives with varying motivations are taking place to develop the battery electric vehicle (BEV) and the fuel cell as alternatives to ICE vehicles, and to establish fuels such as biofuels and natural gas as alternatives to conventional liquid fuels. However, each of these alternatives starts from a very low base and faces significant barriers to fast and unrestrained growth;thus, transport—and particularly commercial transport—will continue to be largely powered by ICEs running on petroleum-based liquid fuels for decades to come. Hence, the sustainability of transport in terms of affordability, energy security, and impact on greenhouse gas (GHG) emissions and air quality can only be ensured by improving ICEs. Indeed, ICEs will continue to improve while using current market fuels, through improvements in combustion, control, and after-treatment systems, assisted by partial electrification in the form of hybridization. However, there is even more scope for improvement through the development of fuel/engine systems that can additionally leverage benefits in fuels manufacture and use components that may be readily available. Gasoline compression ignition (GCI), which uses low-octane gasoline in a compression ignition engine, is one such example. GCI would enable diesel-like efficiencies while making it easier to control nitrogen oxides (NOx) and particulates at a lower cost compared with modern diesel engines. Octane on demand (OOD) also helps to ensure optimum use of available fuel anti-knock quality, and thus improves the overall efficiency of the system.

电控放气阀涡轮增压器在柴油机上的试验研究

在一台满足国六b阶段排放标准的柴油机上,开展电控放气阀涡轮增压器对发动机性能、排放影响的试验研究。试验验证表明:发动机匹配电控放气阀涡轮增压器在发动机中高转速工况对油耗有一定改善,在中低负荷工况能降低油耗、提高排气温度。通过电控放气阀开度特性优化并确定最优的控制参数,在WHTC循环SCR催化器平均温度从226℃提升到246℃,冷态WHTC循环NOx排放降低25%,冷热加权NOx排放降低8.6%。

船用柴油机涡轮辅助EGR系统多参数优化匹配研究

为获得柴油机、排气再循环(EGR)系统和涡轮增压系统的耦合优化匹配运行规律,以SC7H两级增压柴油机为研究对象,在GT-Power软件中搭建并校核原机一维模型,并进一步建立了涡轮辅助EGR两级增压柴油机一维模型。针对涡轮辅助EGR与两级增压耦合系统的匹配问题,提出了基于过量空气系数λ和EGR率需求的三步骤匹配计算流程。匹配规律显示:高/EGR涡轮匹配流量比和高/低压级压比比基本呈线性关系,涡轮辅助EGR进排气压差随压比比增大先增加后减小,在压比比为1附近取最优,比高压EGR高35.35 kPa,涡轮辅助EGR具有更优的泵气过程。建立全连接神经网络优化代理模型并采用NSGAⅡ算法开展耦合系统多参数多目标优化研究。结果显示:涡轮辅助EGR具有更优的BSFC和NOx排放效果,在TierⅢ的加权NOx排放限值条件下,涡轮辅助EGR可调两级增压系统的全负荷加权油耗比传统高压EGR可调两级增压系统低5.20 g/(kW·h)。

基于MPC的电动复合增压柴油机进气压力控制

涡轮增压技术是提高发动机动力性和经济性的主要途径之一,而传统废气涡轮增压在低速区间存在滞后性。电动增压技术能有效弥补涡轮增压技术不足,但增加了控制自由度,电复合增压控制策略是保证其性能的关键,为此提出一种基于模型预测控制(Model Predictive Control,MPC)的电复合柴油机进气控制策略。基于电动增压器数学物理方程,建立了离散预测控制模型和涡轮增压状态观测器与流量观测器;通过联合仿真平台,对控制策略和控制参数进行标定验证;对比不同工况下MPC与传统PID控制效果以及抗电源电压扰动能力。研究结果表明:基于所设计的观测器,控制算法能在不加装额外涡轮转速传感器的前提下,实现对进气压力的有效控制,最大稳态误差≤1%;能有效自适应正常工况下废气涡轮增压器的响应特性,提高低速响应,起步工况下5.2 s内达到目标进气压比;与传统PID控制算法相比,具有更好抗干扰性和控制精度,动态误差降低42%。

催化裂化催化剂LPC-65的工业应用

介绍LPC-65催化裂化催化剂在中国石油兰州石化公司1.20 Mt·a^(-1)重油催化裂化装置上的工业应用。结果表明,当LPC-65催化剂加入量达到系统藏量的50%时,与空白标定期相比,重油转化率和汽油收率分别增加1.24和0.62个百分点,柴油收率降低1.24个百分点,汽油烯烃下降4.09个百分点,异构烷烃和芳烃分别上升4.09个百分点和0.67个百分点。表明使用LPC-65催化剂后,重油转化能力增加,汽油降烯烃效果显著。

基于回归分析的发动机HC排放预测模型

将回归分析方法用在一台经过改造的汽油/柴油双燃料发动机HC排放研究上。以1700r/min@60 N·m工况为例描述了试验设计、模型阶次选择、异常点去除、正态分布假设判断整个过程,获得了精度较高的HC排放模型,通过将试验结果和仿真分析结果进行对比验证了所建模型的正确性。

可变喷嘴增压器喷嘴环叶片位置对柴油机外特性稳态性能的影响

应用GT-SUITE发动机热力学仿真软件对4100柴油机外特性稳态性能进行仿真,研究了喷嘴环叶片位置对废气涡轮增压器和发动机联合运行线、增压器的热力参数、换气过程评价参数和柴油机性能的影响。仿真结果表明:随着喷嘴环开度的增加,发动机运行线下移,喘振裕度增大;压后压力、涡轮前压力随着喷嘴环开度的增加都降低,涡轮前压力降低的幅度要远大于增压后压力降低的幅度,100%开度时压后压力与涡轮前压力相差不大;残余废气系数降低,充气效率增加;功率和有效扭矩增加,燃油消耗率降低。

重型柴油机排气电加热NO_(x)排放控制技术研究

为解决重型柴油机在冷起动工况下的NO_(x)排放恶化问题,基于重型柴油机冷起动试验平台,自主设计了排气电加热系统,并研究了不同电加热功率对后处理后的NO_(x)排放和每度电可处理的NO_(x)排放的影响.结果表明:随着电加热功率从2 kW升高至8 kW,NO_(x)排放逐渐降低,每度电可处理的NO_(x)排放逐渐升高;电加热功率固定为8 kW时,NO_(x)排放达到最低(140.3 mg/(kW·h)),相比原机减少了51.55%;电加热功率固定为2 kW时,每度电可处理的NO_(x)排放最多为1 900.8 mg.基于此,通过仿真进行排气电加热器控制策略的开发,控制策略引入NO_(x)转化效率和燃油消耗量作为判据,每度电可处理的NO_(x)排放增加了19.27%.此时,仅消耗0.21 kW·h电能,即可将后处理后的NO_(x)排放从274.76 mg/(kW·h)降低至231.42 mg/(kW·h).

柴油机电辅助增压系统匹配计算分析

电辅助增压是一种内燃动力机械上常用的有效方法,可解决传统柴油机在小负载时进气压力不足和高负载增压过大的难题。船舶柴油机的增压系统是本文的主要研究对象,并在此基础上完成了柴油机的电气控制系统、涡轮增压辅机模拟模型的建立与验证。结果显示模型仿真预测值与试验值误差不超过2%,模型较为准确。在此基础上,建立电动辅助增压发动机的仿真模型,分析其在低速工况下的动态特性,并探讨其对发动机热效率的影响规律。研究发现,透平和压气机的性能对综合能效有很大的影响。电机功率的增加的同时,缸内燃烧得到改善,有利于发动机低工况下动力性能提升。

舰用倒车汽轮机技术特点及运行过程研究

概要介绍汽轮机的概念与分类,并由此引入其在水面舰船领域的应用。由于汽轮机的结构特点,以及喷嘴和工作叶片的相对位置,在完成安装后,汽轮机的转子只能实现单方向的转动。在水面舰船作机动航行时,汽轮机必须提高倒车功率以提高舰船的机动性,满足航行的需要,保证舰船的航行安全,从而引入倒车汽轮机的定义。重点介绍倒车汽轮机的结构特性、运作过程及工况特点,并将其与能实现反向旋转的柴油机进行对比。除传统的机械式结构外,汽轮机也可与电力推进系统实现搭配,从而提供倒车功率,该类方案则无须配备倒车汽轮机。

柴油机可调两级增压系统调节规律仿真研究

采用GT-POWER建模,对WP7柴油机可调两级增压系统进行模拟计算,分析高压级旁通阀的调节规律。结果表明,增压系统的总压比、低压级压比和高压级压比均随高压级旁通阀开度的增大逐渐下降,其中总压比受旁通阀的开度变化影响最明显,在75%负荷时,随着旁通阀开度的变化,总压比变化幅度达到了2.33。涡轮增压器的总效率随旁通阀开度的增大显著下降,当旁通阀采用蝶阀时,开度大于一定程度后,总效率下降的速度明显趋缓。

水翼船动力装置技术特点及未来发展趋势研究

本文介绍了水翼船的技术特点及我国水翼船行业的发展,以船舶动力装置为论题切入点,阐明了蒸汽机、汽轮机、汽油机、柴油机、燃气轮机、核动力装置及联合动力装置的技术特点,重点对柴油机及燃气轮机两类动力装置在水翼船领域的应用及发展进行了研究。柴油机具有较高的经济性及技术成熟度,曾长期在水翼船动力领域占据重要地位,但考虑到当前水翼船动力性及轻量化等方面的特性要求,航空改型燃气轮机目前在水翼船上有着更好的应用前景。

船用动力装置前景展望

用于船舶推进的发动机被称为主推进发动机(亦称“主机”),其对整个船用动力装置的性能起决定作用,通常会以不同的主机来划分船用动力装置的类型。现代船舶的主机主要有柴油机、汽轮机、燃气轮机及核动力装置等几类。就目前而言,大部分民用船舶,以及部分中、小型军用舰船均采用柴油机;大、中型舰船多采用汽轮机或燃气轮机;联合动力装置可满足水面舰船不同航行工况下的需求;核动力装置能显著提升船舶的续航力和自给力,但需要采用屏蔽装置,重量大、结构复杂,适用于大型航空母舰,大、中型潜艇,以及破冰船与部分大型民用船舶。中、小型潜艇可利用柴油机驱动发电机发电,以电力推进的方式驱动潜艇前行。通过研究船用动力装置,有利于快速掌握其类型、结构、技术特点、使用及管理方法,从而提升其在船舶航行过程中的实际运用效果,提升船舶整体的动力性能。

柴油机电控系统软硬件特征与控制逻辑优化

近年来,柴油机性能升级已经成为生产制造企业的重要工作,尤其在电控技术的支持下,柴油机在工作逻辑、变量控制等方面得到了有效改善,电控技术与柴油机技术的融合度已成为检验柴油机产品市场竞争力的重要影响因素。结合柴油机电控系统实际应用情况,分析了电控系统主要作用和软硬件特征,并提出了控制逻辑的优化建议。