F-T柴油对直喷式柴油机燃烧和排放的影响

在两种不同供油提前角下研究了燃用F-T柴油对直喷式柴油机燃烧和排放特性的影响,结果表明:发动机不做任何调整时,与0号柴油相比,燃用F-T柴油的滞燃期较短,预混燃烧放热峰值较低,扩散燃烧放热峰值较高,最高燃烧压力和最大压力升高率较低,燃油消耗率和热效率都得到了改善,HC、CO、NOx和碳烟排放同时降低。当供油提前角推迟3℃A时,燃用F-T柴油燃烧持续期明显缩短,预混燃烧放热峰值、最高燃烧压力和最大压力升高率进一步降低,扩散燃烧放热峰值略有升高,燃油消耗率变化不大,NOx排放进一步降低, HC、CO和碳烟略有增加,其中HC排放与原柴油机相当,而CO和碳烟仍远低于原柴油机。     

生物柴油/甲醇混合燃料对柴油机性能与排放的影响研究

在一台4缸直喷式柴油机上研究了超低硫柴油、生物柴油及后者与甲醇的混合燃料对发动机性能、气体及微粒排放的影响。生物柴油由餐饮废油制取,除单独使用外和甲醇按体积比90：10和80：20混合后使用。在最大扭矩转速1800 r.m in-1时,在5个不同负荷下,比较了不同燃料热效率及CO、HC、NOx以及微粒质量浓度,微粒的总数量及平均几何粒径。结果表明,和超低硫柴油相比,生物柴油及其和甲醇的混合燃料的热效率增加,NOx和微粒质量、数量浓度的排放降低,但HC、CO和NO2排放升高;同时,随着甲醇混合比例的增加,HC、CO和NO2的排放成比例增加,微粒的质量浓度及数量浓度进一步降低,热效率及NOx几乎保持不变。     

Performance and emission characteristics of CIE using hydrogen,biodiesel, and massive EGR

Hydrogen is considered as an excellent energy carrier and can be used in diesel engines that operate in dual fuel mode. Many studies have shown that biodiesel, which is sustainable, clean, and safe, a good alternative to fossil fuel. However, tests have confirmed that using biodiesel or hydrogen as a fuel or added fuel in compression ignition engines increases NOx concentrations. Cooled or hot exhaust gas recirculation (EGR) effectively controls the NOx outflows of diesel engines. However, this technique is restricted by high particulate matter PM emissions and the low thermal efficiency of diesel engines.In this study, gaseous hydrogen was added to the intake manifold of a diesel engine that uses biodiesel fuel as pilot fuel. The investigation was conducted under heavy-EGR conditions. An EGR system was modified to achieve the highest possible control on the EGR ratio and temperature. Hot EGR was recirculated directly from the engine exhaust to the intake manifold. A heat exchanger was utilized to maintain the temperature of the cooled EGR at 25 °C.The supplied hydrogen increased NOx concentrations in the exhaust gas emissions and high EGR rates reduced the brake thermal efficiency. The reduction in NOx emissions depended on the added hydrogen and the EGR ratios when compared with pure diesel combustion. Adding hydrogen to significant amounts of recycled exhaust gas reduced the CO, PM, and unburned hydrocarbon (HC) emissions significantly. Results showed that using hydrogen and biodiesel increases engine noise, which is reduced by adding high levels of EGR.     

燃烧参数对汽油/柴油双燃料HPCC性能和排放影响的试验

在一台改造的单缸柴油机上,转速为1,500,r/min、平均指标压力为0.9,MPa工况进行了不同参数对汽油/柴油双燃料高比例预混合低温燃烧(HPCC)方式燃烧和排放性能影响的试验研究.结果表明,调整EGR率和汽油比例可实现HPCC燃烧过程优化,在保持发动机高燃油经济性的前提下使NOx和碳烟(Soot)排放大幅降低;进气压力对Soot的影响不明显,但进气压力过低将限制汽油比例的提高,NOx排放偏高,进气压力过高使燃烧效率和热效率降低;提高柴油喷油压力,滞燃期延长,最大压升率及最大爆发压力降低;提高喷油压力可同时降低NOx和Soot排放,但喷油压力对燃烧效率、指示油耗、HC和CO排放影响不大.在HPCC燃烧中,通过优化EGR率、汽油比例、进气压力和柴油喷油压力,在不使用后处理器的前提下可使NOx和Soot排放分别低于0.4,g/(kW.h)和0.003,g/(kW.h),并保持较高的热效率,但HC和CO排放偏高,需要采用有较高转换效率的氧化后处理器加以解决.     

Effect of addition of hydrogen and exhaust gas recirculation on characteristics of hydrogen gasoline engine

The effects of exhaust gas recirculation (EGR) on combustion and emissions under different hydrogen ratios were studied based on an engine with a gasoline intake port injection and hydrogen direct injection. The peak cylinder pressure increases by 9.8% in the presence of a small amount of hydrogen. The heat release from combustion is more concentrated, and the engine torque can increase by 11% with a small amount of hydrogen addition. Nitrogen oxide (NOx) emissions can be reduced by EGR dilution. Hydrogen addition offsets the blocking effect of EGR on combustion partially, therefore, hydrogen addition permits a higher original engine EGR rate, and yields a larger throttle opening, which improves the mechanical efficiency and decreases NOx emissions by 54.8% compared with the original engine. The effects of EGR on carbon monoxide (CO) and hydrocarbon (HC) emissions are not obvious and CO and HC emissions can be reduced sharply with hydrogen addition. CO, HC, and NOx emissions can be controlled at a lower level, engine output torque can be increased, and fuel consumption can be reduced significantly with the co-control of hydrogen addition and EGR in a hydrogen gasoline engine.     

柴油/甲醇组合燃烧增压中冷发动机的甲醛及常规排放特性

为了研究柴油/甲醇组合燃烧(DMCC)方式对发动机排放性能的影响,在增压中冷发动机上采用DMCC方式,对甲醛排放特性进行研究,另外在DMCC模式下对加装氧化催化转换器前后常规排放进行对比.结果表明:在各负荷下,甲醛排放均随着甲醇喷射量的增加而升高;在甲醇喷射量不变的情况下,甲醛排放随着负荷的增加明显降低.增压中冷发动机的NOx和碳烟及微粒排放同时大幅度下降,但HC和CO排放增加较多.加装氧化催化转化器后,HC和CO排放得到了大幅度降低,微粒排放也进一步减少.     

柴油机掺烧DMM的燃烧和排放性能影响研究

研究了柴油掺混不同比例二甲氧基甲烷(0～50%DMM)对柴油机燃烧和排放性能的影响.结果表明,在发动机燃油和燃烧系统不作变动的条件下,随着二甲氧基甲烷在柴油中添加比例的增加,排气烟度逐步下降,有效燃油消耗率有所增加,但折算成当量柴油的有效燃油消耗率降低,热效率增加.同一工况下,发动机排气碳烟和CO排放随二甲氧基甲烷的加入而降低,NOx则无明显的上升,HC排放随着二甲氧基甲烷的增加略有增加.混合燃料的放热规律与纯柴油相比预混燃烧量增加,扩散燃烧速率加快,发动机最高燃烧压力、放热率偏高.柴油掺混30%DMM的混合燃料能够取得较好的燃油经济性和排放水平.     

Experimental study of engine performance and emissions for hydrogen diesel dual fuel engine with exhaust gas recirculation

With an alarming enlargement in vehicular density, there is a threat to the environment due to toxic emissions and depleting fossil fuel reserves across the globe. This has led to the perpetual exploration of clean energy resources to establish sustainable transportation. Researchers are continuously looking for the fuels with clean emission without compromising much on vehicular performance characteristics which has already been set by efficient diesel engines. Hydrogen seems to be a promising alternative fuel for its clean combustion, recyclability and enhanced engine performance. However, problems like high NOx emissions is seen as an exclusive threat to hydrogen fuelled engines. Exhaust gas recirculation (EGR), on the other hand, is known to overcome the aforementioned problem. Therefore, this study is conducted to study the combined effect of hydrogen addition and EGR on the dual fuelled compression ignition engine on a single cylinder diesel engine modified to incorporate manifold hydrogen injection and controlled EGR. The experiments are conducted for 25%, 50%, 75% and 100% loads with the hydrogen energy share (HES) of 0%, 10% and 30%. The EGR rate is controlled between 0%, 5% and 10%. With no substantial decrement in engine's brake thermal efficiency, high gains in terms of emissions are observed due to synergy between hydrogen addition and EGR. The cumulative reduction of 38.4%, 27.4%, 33.4%, 32.3% and 20% with 30% HES and 10% EGR is observed for NOx, CO2, CO, THC and PM, respectively. Hence, the combination of hydrogen addition and EGR is observed to be advantageous for overall emission reduction.     

Effect of hydrogen and LPG addition on the efficiency and emissions of a dual fuel diesel engine

This paper presents some experimental investigations on dual fuel operation of a 4 cylinder (turbocharged and intercooled) 62.5 kW gen-set diesel engine with hydrogen, liquefied petroleum gas (LPG) and mixture of LPG and hydrogen as secondary fuels. Results on brake thermal efficiency and emissions, namely, un-burnt hydrocarbon (HC), carbon monoxide (CO), NO_x and smoke are presented here. The paper also includes vital information regarding performances of the engine at a wide range of load conditions with different gaseous fuel substitutions. When only hydrogen is used as secondary fuel, maximum enhancement in the brake thermal efficiency is 17% which is obtained with 30% of secondary fuel. When only LPG is used as secondary fuel, maximum enhancement in the brake thermal efficiency (of 6%) is obtained with 40% of secondary fuel. Compared to the pure diesel operation, proportion of un-burnt HC and CO increases, while, emission of NO_x and smoke reduces in both cases. On the other hand, when 40% of mixture of LPG and hydrogen is used (in the ratio 70:30) as secondary fuel, brake thermal efficiency enhances by 27% and HC emission reduces by 68%. Further, shortcoming of low efficiency at lower load condition in a dual fuel operation is removed when a mixture of hydrogen and LPG is used as the secondary fuel at higher than 10% load condition.     

甲醇-汽油混合燃料对汽油机性能影响的试验研究

在一台多点电喷汽油机上,开展了燃用不同掺混比的甲醇-汽油混合燃料时发动机的经济性、排放特性研究。结果表明:电喷汽油机燃用低掺混比甲醇-汽油(小于30%)时,随着甲醇掺混比的增加,经济性有所改善,有效热效率明显提高;CO的排放有明显改善,中低负荷时HC排放有所改善,高负荷时HC排放增加,NOx排放相当,而怠速工况时,排放特性变差。     

Hydrogen effects on the diesel engine performance and emissions

In this research, effects of hydrogen addition on a diesel engine were investigated in terms of engine performance and emissions for four cylinders, water cooled diesel engine. Hydrogen was added through the intake port of the diesel engine. Hydrogen effects on the diesel engine were investigated with different amount (0.20, 0.40, 0.60 and 0.80 lpm) at different engine load (20%, 40%, 60%, 80% and 100% load) and the constant speed, 1800 rpm. When hydrogen amount is increased for all engine loads, it is observed an increase in brake specific fuel consumption and brake thermal efficiency due to mixture formation and higher flame speed of hydrogen gas according to the results. For the 0.80 lpm hydrogen addition, exhaust temperature and NOx increased at higher loads. CO, UHC and SOOT emissions significantly decreased for hydrogen gas as additional fuel at all loads. In this study, higher decrease on SOOT emissions (up to 0.80lpm) was obtained. In addition, for 0.80 lpm hydrogen addition, the dramatic increase in NOx emissions was observed.     

甲醇-汽油混合燃料电喷汽油机性能的试验研究

在一台多点电喷汽油机上,系统开展了燃用高比例的甲醇汽油混合燃料(甲醇的体积比为85%)M85时发动机的动力性,经济性和排放特性。研究结果表明:电喷汽油机燃用M85时,动力性明显改善,经济性明显提高,有效热效率明显提高;CO和NOx的排放有明显改善,但HC排放明显恶化。     

Effect of addition of hydrogen and TiO2 in gasoline engine in various exhaust gas recirculation ratio

The effects of hydrogen ratios on combustion and emission characteristics of gasoline engine were studied under different exhaust gas recirculation (EGR), ignition timing and ignition pressure. The test performed in a modified gasoline direct ignition engine at different hydrogen ratios of 0%, 5%, 10% and 25%. In addition, the EGR rate set to 0%, 5%, 10% and 20% to study the combustion and emission characteristics. Addition to the different hydrogen fractions, 5% of TiO₂ is added to increase the combustion characteristics with reduced emission. Regarding the results of the current study, the engine torque increases by 15% due to the addition of hydrogen in gasoline, while mechanical efficiency is improved by achieving a large throttle opening. At the same time, NOx emission decreased by 62% compared to the unmodified engine due to the influence of EGR, hydrogen ratio and high oxygen concentration TiO₂. Moreover, the emission of CO and HC also reduced due to the influence of hydrogen fuel. Additionally, few more tests are taken to monitor the effect of the injection pressure for the hydrogen fuel. Higher injection reports higher effective thermal efficiency at 4 MPa and lower NOx. Reasonable injection pressure results in shorten flame development period.     

Studies on the effect of hydrogen induction on performance,emission and combustion behaviour of a WCO emulsion based dual fuel engine

This paper aims at studying the effect of hydrogen induction on engine performance, emission and combustion behaviour of a diesel engine fuelled with the emulsion of used palm oil (called as WCO-waste cooking oil) as pilot fuel and hydrogen as primary fuel. A single cylinder water-cooled direct injection diesel engine was tested at 100% and 40% loads. Results were compared with neat diesel, neat WCO and WCO emulsion at both loads in single fuel operation. WCO emulsion in single fuel mode indicated improvement in performance and reduction in all emissions as compared to neat WCO. Dual fuel operation with hydrogen induction further reduced the emissions of smoke HC and CO with WCO as pilot fuel at all power outputs. However, hydrogen induction resulted in reduced thermal efficiency at 40% load. WCO emulsion showed higher ignition delay as compared to neat WCO. Dual fuel operation with hydrogen induction increased the ignition delay further. Heat release pattern showed higher premixed combustion rate with hydrogen induction mainly at high power outputs. Premixed combustion rate became very high at higher rates of hydrogen admission mainly at high power output. In general, hydrogen induction showed superior performance at high power output and inferior performance at low power output with WCO emulsion as injected fuel.     

汽油/柴油双燃料高比例预混压燃燃烧与排放的试验

对汽油/柴油双燃料高比例预混燃烧(HPCC)模式的燃烧及排放特性进行了初步的试验研究.结果表明,通过改变柴油的喷射时刻、汽油比例,HPCC呈现出由多种燃烧模式组成的复合燃烧模式,可以实现极低的NOx和碳烟排放,并能保持较高的热效率.试验工况下,汽油比例为50%时,柴油喷油时刻在-58～-6,°CA ATDC时热效率较高,喷油时刻在-49,°CA ATDC和-16,°CA ATDC时分别出现碳烟和NOx排放峰值.进气压力影响HPCC着火滞燃期、燃烧反应速度和"失火"与"爆震"燃烧汽油比例限值,提高进气压力可以提高汽油比例,实现超低的NOx和碳烟排放,并降低HC排放,但CO排放有所升高.随着汽油比例的增加,NOx与碳烟排放降低,对于IMEP为0.5,MPa、汽油比例大于50%时,两者的原始排放分别低于0.4,g/(kW.h)、0.06,FSN,但HC和CO排放升高.     

基于目标起动转速变化规律的起动过程瞬态喷油量控制策略研究

提出了一种基于目标起动转速变化规律的起动过程瞬态喷油量的控制策略以改善柴油机起动性能,详细介绍了这种控制策略的起动过程瞬态喷油量的确定方法,并在2.8T型4缸直喷高压共轨柴油机上与恒定油量控制方法和标定转矩MAP控制方法进行了台架对比试验。结果表明:标定转矩MAP控制方式虽然NO_x排放量最低,但燃烧效率普遍较低,HC与CO排放水平较高;而基于目标转速变化规律的控制策略可根据起动过程中目标转速的变化所对应的需求转矩精确地控制起动过程各循环的瞬态喷油量,实现对起动过程喷油量的循环控制,使各循环燃烧效率均保持在高水平,有效地降低了CO_2排放,且在保持HC和CO排放水平较低的前提下明显降低了NO_x排放量,同时很好地改善了起动到怠速的过渡过程转速的波动现象。     

Combustion and emissions behaviour for ethanol–gasoline-blended fuels in a multipoint electronic fuel injection engine

The study investigated the combustion and emissions of a gasoline engine using ethanol–gasoline blends. The results indicated that the peak cylinder pressure of E10 is evidently lower, but that of E20 is identical to that of gasoline. At lower engine loads, the combustion velocity of gasoline is faster, and the peak heat release rate (HRR) is higher than that of the blends, but at higher engine loads, E20 shows faster combustion velocity and a little higher peak HRR. The brake thermal efficiency of the blends is almost similar to that of gasoline, but the brake-specific fuel consumption of the blends is slightly higher. With the increase in ethanol content in the blends, CO evidently decreases, HC slightly increases at high engine loads, and NOx depends on the engine operating conditions as well as the ethanol content. The acetaldehyde of the blends is evidently and the ethanol is slightly higher than that of gasoline.     

柴油机燃用生物柴油的排放特性研究

生物柴油来自于动植物油脂的单酯衍生物,是一种可再生的替代能源。脂肪酸单酯作为发动机燃料的可行性来自于其分子结构和较高的能量密度。柴油机燃用生物柴油与0^#柴油具有几乎一致的热效率。在同一稳定工况下,随着生物柴油加入比例的增加,生物柴油与0^#柴油混合燃料燃烧产生的排放物中CO和HC比排放呈现线性下降,NOx比排放有所增加,而CO2比排放维持在同一水平。     

Combustion and emission characteristics of a hydrogen-diesel dual-fuel engine

Hydrogen generated from renewable sources is an eco-friendly fuel that can be used in automotive industry or for energy generation purposes. Hydrogen is a high-energy content gas and its carbonless chemical structure can provide significant benefits of high thermal efficiency and near zero or very low carbon emissions when combusted with other fuels.In this study, the implementation of hydrogen fuel was tested at low and medium operating loads in a heavy-duty hydrogen-diesel dual-fuel engine. The paper provides a detailed experimental analysis of the effects of hydrogen energy share ratio and various combustion strategies such as exhaust gas recirculation, diesel injection pressure and diesel injection patterns.At low load conditions, engine operation with an H₂ energy share ratio of up to 98% was achieved without any engine operation implications. This condition provided a simultaneous reduction of carbon and NOx emission of over 90% while soot emissions were dropped by 85% compared to the conventional diesel-only operation. At medium load, the increased NOx emission due to the high energy content of hydrogen fuel was found to be the primary challenge.     

Effects of Fischer-Tropsch diesel fuel on combustion and emissions of direct injection diesel engine

Effects of Fischer-Tropsch (F-T) diesel fuel on the combustion and emission characteristics of a single-cylinder direct injection diesel engine under different fuel delivery advance angles were investigated. The experimental results show that F-T diesel fuel exhibits shorter ignition delay, lower peak values of premixed burning rate, lower combustion pressure and pressure rise rate, and higher peak value of diffusion burning rate than conventional diesel fuel when the engine remains unmodified. In addition, the unmodified engine with F-T diesel fuel has lower brake specific fuel consumption and higher effective thermal efficiency, and presents lower HC, CO, NO_x and smoke emissions than conventional diesel fuel. When fuel delivery advance angle is retarded by 3 crank angle degrees, the combustion duration is obviously shortened; the peak values of premixed burning rate, the combustion pressure and pressure rise rate are further reduced; and the peak value of diffusion burning rate is further increased for F-T diesel fuel operation. Moreover, the retardation of fuel delivery advance angle results in a further significant reduction in NO_x emissions with no penalty on specific fuel consumption and with much less penalty on HC, CO and smoke emissions.