用光学可视化方法研究乙醇柴油混合燃料的燃烧特征

应用直接图像法对乙醇柴油的燃烧过程进行研究。在一台单缸直接喷射式柴油机上,建立了直接图像法拍摄燃烧火焰图像的光学系统,对15%乙醇柴油、15%乙醇柴油加十六烷值改进剂、纯柴油在同一转速下的燃烧过程进行可视化研究。对火焰照片分析表明:柴油中加入乙醇后,无论是否恢复其十六烷值,其着火滞燃期都延长了,燃烧持续期缩短,火焰辉度减弱。在乙醇柴油中加入十六烷值改进剂后,着火滞燃期相对提前,燃烧持续期和火焰辉度增加,但仍然没有达到柴油机水平,这说明十六烷值改进剂有利于改善乙醇柴油的燃烧性能。通过温度场分析发现:乙醇柴油的缸内平均温度峰值要比纯柴油低很多,而且乙醇柴油燃烧时平均温度上升相当平缓。     

生物制气发动机最大扭矩转速燃烧排放分析

介绍了采用气化炉热解气化各种农林废弃的生物质,得到可燃生物制气。将柴油机改制成柴油/生物制气双燃料发动机进行试验,用生物制气作为主要燃料,由柴油引燃。测量生物制气/柴油双燃料发动机在最大扭矩转速时的气缸压力及废气排放,分析燃烧特性及对排放物生成的影响,并对比分析柴油机与双燃料发动机的差别。     

Reduction of emissions with propane addition to a diesel engine

Recent studies on dual-fuel combustion in compression-ignition (CI) engines, also known as diesel engines, fall into two categories. In the first category are studies focused on the addition of small amounts of gaseous fuel to CI engines. In these studies, gaseous fuel is regarded as a secondary fuel and diesel fuel is regarded as the main fuel for combustion. The objectives of these studies typically involve reducing particulate matter (PM) emissions by using gaseous fuel as a partial substitution for diesel fuel. However, the addition of gaseous fuel raises the combustion temperature, which increases emissions of nitrogen oxides (NO_x). In the second category are studies focused on reactivity-controlled compression-ignition (RCCI) combustion. RCCI combustion can be implemented by early diesel injection with a large amount of low-reactivity fuel such as gasoline or gaseous fuel. Although RCCI combustion promises lower NO_x and PM emissions and higher thermal efficiency than conventional diesel combustion, it requires a higher intake pressure (usually more than 1.7 bars) to maintain a lean fuel mixture. Therefore, in this study, practical applications of dual-fuel combustion with a low air-fuel ratio (AFR), which implies a low intake pressure, were systemically evaluated using propane in a diesel engine. The characteristics of dualfuel combustion for high and low AFRs were first evaluated. The proportion of propane used for four different operating conditions was then increased to decrease emissions and to identify the optimal condition for dual-fuel combustion. Although the four operating conditions differ, the AFR was maintained at 20 (? approximately equal to 0.72) and the 50% mass fraction burned (MFB 50) was also fixed. The results show that dual-fuel combustion can reduce NO_x and PM emissions in comparison to conventional diesel combustion.     

Operating strategy for gasoline/diesel dual-fuel premixed compression ignition in a light-duty diesel engine

Environmental problems have become a major issue for diesel engine development. Although emission aftertreatment systems such as DPFs (diesel particulate filters), LNTs (lean NOx traps) and SCR (selective catalytic reduction) have been used in diesel vehicles, the manufacturing cost increase caused by this equipment can be hard to be control. Thus, it is better for engine emissions to be reduced by improving the combustion system. A dual-fuel combustion concept is a recommended method to improve a combustion system and effectively reduce emissions. Low reactivity fuel including gasoline and natural gas, which was supplied to the intake port by the FPI (port fuel injector), improved the premixed air-fuel mixture conditions before ignition. Additionally, a small amount of high reactivity fuel, in this case diesel, was injected into the cylinder directly as an ignition source. This dual-fuel combustion promises lower levels of NOx (nitrogen oxide) and PM (particulate matter) emissions due to the elimination of local rich regions in the cylinder. However, it is challenging to control the dual-fuel combustion because the combustion stability and efficiency deteriorate due to the lack of ignition source and reactivity. Thus, it is important to establish an appropriate dual-fuel operating strategy to achieve stable, high efficiency and low emission operation. As a result of this research, a detailed operating method of dual-fuel PCI (premixed compression ignition) was introduced in detail at a low speed and low load condition by using a single cylinder diesel engine. Engine operating parameters including the gasoline ratio, a diesel injection strategy consisting of multiple injectors and timing, the EGR (exhaust gas recirculation) rate and the intake pressure were controlled to satisfy the low ISNOx (indicated specific NOx) and PM emissions levels (0.21 g/kWh and 0.1 FSN, 0.040 g/kWh, respectively) as per the EURO-6 regulation without any after-treatment systems. The results emphasized that a well-constructed dual-fuel PCI operating strategy showed low NOx and PM emissions and high GIE (gross indicated fuel conversion efficiency) with excellent combustion stability.     

Influence of injection parameters on the transition from PCCI combustion to diffusion combustion in a small-bore HSDI diesel engine

In this paper, the influence of injection parameters on the transition from Premixed Charge Combustion Ignition (PCCI) combustion to conventional diesel combustion was investigated in an optically accessible High-Speed Direct-Injection (HSDI) diesel engine using multiple injection strategies. The heat release characteristics were analyzed using incylinder pressure for different operating conditions. The whole cycle combustion process was visualized with a high-speed video camera by simultaneously capturing the natural flame luminosity from both the bottom of the optical piston and the side window, showing the three dimensional combustion structure within the combustion chamber. Eight operating conditions were selected to address the influences of injection pressure, injection timing, and fuel quantity of the first injection on the development of second injection combustion. For some cases with early first injection timing and a small fuel quantity, no liquid fuel is found when luminous flame points appear, which shows that premixed combustion occurs for these cases. However, with the increase of first injection fuel quantity and retardation of the first injection timing, the combustion mode transitions from PCCI combustion to diffusion flame combustion, with liquid fuel being injected into the hot flame. The observed combustion phenomena are mainly determined by the ambient temperature and pressure at the start of the second injection event. The start-of-injection ambient conditions are greatly influenced by the first injection timing, fuel quantity, and injection pressure. Small fuel quantity and early injection timing of the first injection event and high injection pressure are preferable for low sooting combustion.     

掺烧比对P50/甲醇双燃料发动机燃烧与排放的影响

燃料富氧重整和双燃料燃烧模式是改善燃烧过程和降低颗粒物排放的重要方法.在一台四缸增压中冷的高压共轨柴油机上,采用进气道喷射甲醇、缸内喷射P50(50％体积比例柴油与50％体积比例PODE)的双燃料模式,研究掺混比对P50/甲醇双燃料发动机燃烧与排放特性的影响.研究结果表明:相比于纯柴油模式,P50及P50/甲醇双燃料燃...     

WP10.336柴油/天然气双燃料发动机试验研究

将WP10.336柴油机改变为双燃料发动机并进行了标定和试验。试验结果表明,双燃料发动机的动力性与原柴油机相当,外特性线上平均柴油替代率达到95.7%。双燃料发动机在1200 r/min时,中、高负荷下都有较高的热效率和柴油替代率,最大功率点对应的缸内最高爆发压力为14.82 MPa。     

双燃料发动机低负荷时替代率的选取

随着国家对于排放问题的不断重视以及越来越严格的排放标准,将柴油发动机改装成为天然气-柴油双燃料发动机便成为行之有效的一个措施。在改装过程中,如何确定引燃油量的多少成为核心问题。文章针对双燃料发动机在油门开度为25%的低负荷,固定转速下,通过Converge软件仿真研究引燃油量对发动机动力性和经济性的影响并选取合适的替代率。对于双燃料发动机的改装具有参考价值。     

生物柴油-柴油-乙醇混合燃料的燃烧与排放特性

为了改善发动机燃用高比例生物质混合燃料的性能,在中等比例的生物柴油-柴油混合燃料中分别添加5%、10%和20%体积比的乙醇（分别用BD50E5,BD50E10和BD50E20表示）,在一台6缸增压共轨柴油机上,将发动机的转速稳定在1 600 r·min^-1,选择7个不同的负荷点测定不同掺混比生物柴油-柴油-乙醇混合燃料的燃烧与排放性能,并将其与柴油进行对比。结果表明：在平均有效压力为0.322 MPa的低负荷条件下,发动机为预喷加主喷喷油策略,在预喷的低温反应阶段生物柴油-柴油-乙醇混合燃料产生了大量羟基自由基,因此混合燃料的缸内最大压力和最大瞬时放热率均高于柴油;随着负荷的增大,当平均有效压力为0.805 MPa时,发动机的喷油策略转变为单段喷射,乙醇的热值较低导致生物柴油-柴油-乙醇混合燃料的缸内最大压力和最大瞬时放热率低于柴油;随着乙醇掺混比的增大,受乙醇低十六烷值和高汽化潜热的影响,生物柴油-柴油-乙醇混合燃料的滞燃期明显延长;强烈的预混燃烧和乙醇的高含氧量使混合燃料的燃烧速度明显加快,乙醇的添加有利于燃料集中放热从而缩短燃烧持续期;与纯柴油相比,BD50E5,BD50E10和BD50E20的NO_x排放量分别升高了10.46%、12.59%和17.52%,碳烟排放量分别降低了37.91%、45.85%和49.25%,CO排放量分别降低了20.24%、36.43%和46.43%,HC排放量分别降低了12.53%、4.40%和0.76%。     

D6114柴油/CNG双燃料发动机的试验研究

D6114柴油/CNG双燃料增压中冷发动机当以双燃料方式工作时,发动机起动和怠速只燃用柴油;当转速超过某设定值,电控系统发出指令限制柴油的喷油量,天然气经混合器进入气缸参与燃烧,此时少量柴油供给主要起引燃作用,发动机负荷变化则通过改变天然气供给量的大小来实现。分析了进气温度、替代率、供油提前角对性能和排放的影响,指出按NMHC排放衡量,该双燃料发动机完全可以达到ECER49欧I标准。     

氨燃料汽车发动机燃烧技术研究进展

为缓解全球气候变暖,可考虑在汽车发动机上燃烧零碳氨燃料以减少碳排放。但由于氨(NH₃)的燃点高、最小点火能量高以及燃烧缓慢等劣势,需要借助氢气(H₂)作为助燃剂,帮助改善氨燃料发动机的燃料燃烧过程。针对国内外相关文献进行综述,总结了氨氢双燃料发动机掺混燃烧调控方法的研究进展,并分析了氨催化分解制氢与氨燃料发动机耦合的研究现状,发现采用氨燃料在线重整制氢可以避免采用双燃料供给系统。研究结果表明,氢气助燃能提高氨燃料发动机的燃烧速度,降低NO_x的排放量。对于氨燃料发动机依旧存在的动力性能下降和未燃氨气排放等问题,仍需在今后的研究中探索解决。     

降低柴油/LPG双燃料发动机碳烟排放的试验研究

针对城市公交柴油客车一直难以解决的碳烟排放问题进行了大量的试验研究,开发出一种柴油／LPG 双燃料发动机用的燃料供给和控制系统。经柴油机改装和装备该系统的柴油／LPG双燃料发动机在运行过程中能 够在柴油运行模式和柴油／LPG双燃料运行模式之间平稳切换,在双燃料运行模式下能够保证发动机的动力性和 经济性,碳烟排放大幅度降低,最大可降低至柴油工况的80％。     

柴油-天然气双燃料发动机的性能研究

在高压共轨电控柴油发动机的基础上,研发了柴油-天然气双燃料发动机。该发动机在原机电控系统保持不变的情况下,增加了一套双燃料电控系统,使其可以在纯柴油和柴油天然气双燃料两种模式下工作。在柴油天然气双燃料模式下,以少量的柴油引燃适量的天然气进行混合燃烧,达到与原机相同的功率及扭矩输出,天然气对柴油的平均替代率达85%以上,提高了该发动机的经济性。     

Influence of turpentine addition in Jatropha biodiesel on CI engine performance,combustion and exhaust emissions

The prospect of using turpentine oil as an additive for Jatropha biodiesel and using it as an alternative fuel for diesel in CI engines has been experimented in this work. Tests were carried out in a single cylinder, air cooled, constant speed, direct injection diesel engine. The results display that the performance of Jatropha-Mineral Turpentine (JMT) and Jatropha- Wood Turpentine (JWT) blends were found close to diesel, emission features were enhanced and combustion parameters were noticed to be comparable with diesel. Brake thermal efficiency of JMT20 blend found closer to diesel at 75 % load. BSFC increases for JMT and JWT blends at part load and maintains at full load. CO, HC and Smoke emissions were reduced with JMT and JWT blends at 75 % load. NOx emissions were on the raise. Furthermore, JMT and JWT blends offered comparable performance and combustion parameters, reduced emissions and both can substitute standard diesel in CI engines.     

CA6110ZLA5N2柴油/天然气双燃料发动机的开发

为了达到欧Ⅱ排放法规要求和满足日益增长的对代用燃料发动机的需求,开发了一种以天然气和柴油为燃料的CA6110ZLA5N2双燃料发动机。该发动机采用增压中冷技术,匹配新型高效增压器,采用单点电控喷气系统,采取空燃比、天然气和柴油供给量精确控制的稀薄燃烧方式,增设用于天然气废气的特殊催化器,使该发动机不仅具有原柴油机的动力性,而且排放可满足欧Ⅱ标准的要求。     

电喷汽油机爆燃控制的策略及试验研究

介绍了BOSCH汽油机电喷系统爆燃识别及爆燃控制的策略,分析讨论了带有爆燃控制的发动机管理系统在协调发动机动力性、经济性与爆燃安全性等方面的优势,试验研究了不同爆燃情况下的发动机性能及排放的差异,以及系统过量空气系数和进气温度与爆燃边界点火提前角的关系。     

高压共轨燃油系统后喷射控制研究

根据柴油机后喷射作用机理,以有效降低燃烧噪声、减少排放为目的,分析设计高压共轨燃油喷射系统后喷射控制策略,解决后喷射控制中有关喷射协调、后喷射量、喷射起始时刻、喷射器作用时间和喷射释放以及相关参数修正等问题。     

Effect of operating parameters on diesel/propane dual fuel premixed compression ignition in a diesel engine

In this research, the effects of three operating parameters (Diesel injection timing, propane ratio, and exhaust gas recirculation (EGR) rates) in a diesel-propane dual fuel combustion were investigated. The characteristics of dual-fuel combustion were analyzed by engine parameters, such as emission levels (Nitrogen oxides (NO_x) and particulate matter (PM)), gross indicated thermal efficiency (GIE) and gross IMEP Coefficient of Variance (CoV). Based on the results, improving operating strategies of the four main operating points were conducted for dual-fuel PCCI combustion with restrictions on the emissions and the maximum pressure rise rate. The NOx emission was restricted to below 0.21 g/kWh in terms of the indicated specific NO_x (ISNO_x), PM was restricted to under 0.2 FSN, and the maximum pressure rise rate (MPRR) was restricted to 10 bar/deg. Dual-fuel PCI combustion can be available with low NO_x, PM emission and the maximum pressure rise rate in relatively low load condition. However, exceeding of PM and MPRR regulation was occurred in high load condition, therefore, design of optimal piston shape for early diesel injection and modification of hardware optimizing for dual-fuel combustion should be taken into consideration.     

满足欧Ⅴ排放标准的轿车主流动力

通过对汽油机、柴油机及其他新型轿车动力作最新动态的分析和比较,预测满足未来欧Ⅴ排放标准的轿车主流动力为新型高清洁绿色柴油机;并从燃油喷射技术、着火技术、中冷技术、燃烧过程以及后处理技术等方面论述了新型柴油机的先进性;随着排放法规的不断严格以及世界石油危机的加剧,预测混合动力和H2燃料电池将会在适当的时期成为轿车主流动力。     

Effect of fuel injection strategies on the combustion process in a PFI boosted SI engine

A low-cost solution based on fuel injection strategies was investigated to optimize the combustion process in a boosted port fuel injection spark ignition (PFI SI) engine. The goal was to reduce the fuel consumption and pollutant emissions while maintaining performance. The effect of fuel injection was analyzed for the closed and open valve conditions, and the multiple injection strategies (MIS) based on double and triple fuel injection in the open-valve condition. The tests were performed on an optical accessible single-cylinder PFI SI engine equipped with an external boost device. The engine was operated at full load and with a stoichiometric ratio equivalent to that of commercial gasolines. Optical techniques based on 2D-digital imaging were used to follow the flame propagation from the flame kernel to late combustion phase. In particular, the diffusion-controlled flames near the valves and cylinder walls, due to fuel deposition, were studied. In these conditions, the presence of soot was measured by two-color pyrometry, and correlated with engine parameters and exhaust emissions measured by conventional methods. The open valve fuel injection strategies demonstrated better combustion process efficiency than the closed ones. They provided very low soot levels in the combustion chamber and engine exhaust, and a reduction in specific fuel consumption. The multiple injection strategies proved to be the best solution in terms of performance, soot concentration, and fuel consumption.