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TCD燃烧系统对柴油机燃烧和排放性能改善效果的试验研究 被引量:3

Experimental study on the improvement effects of TCD combustion system on combustion and emission performance of diesel engine
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摘要 为探究道依茨TCD2015柴油机上配备的导流燃烧系统(简称TCD燃烧系统,T表示涡轮增压器,Turbocharger,C表示进气中冷,Charge air cooling,D为柴油颗粒捕集器,Diesel particle filter)对改善柴油机燃烧性能和降低污染物排放的效果,采用单缸机试验对TCD燃烧系统在不同转速、负荷和过量空气系数下的燃烧和排放性能进行研究。试验结果表明不同工况下TCD燃烧系统燃油消耗率和Soot排放量均低于传统ω燃烧系统,燃油消耗率最大降幅为7.01%,Soot排放量最大降幅为86.67%,且低过量空气系数(1.2~1.6)下TCD燃烧系统仍具有较好的性能。为揭示TCD燃烧系统改善油气混合促进燃烧的机理,采用AVL Fire软件建立了柴油机性能仿真模型。计算结果表明,TCD燃烧系统的环状凸起结构将燃油导向内外两室,从而促进了缸内燃油发展过程,燃油当量比大于4的浓混合气区域燃油质量比例相比ω燃烧系统降幅最大为9.75%,活塞下移时TCD燃烧系统内油束撞击浅盘侧壁形成撞壁射流扩大了燃油扩散面积,从而改善了缸内油气混合质量,燃油当量比小于1的均匀混合气区域燃油质量比例相比ω燃烧系统降幅最大为7.45%,因此TCD燃烧系统能够有效改善柴油机的燃烧和排放性能,可应用于柴油机高负荷和低过量空气系数工况综合性能提升。研究结果可为柴油机燃烧系统开发和改进提供参考。 Diesel engines find wide use in the mechanic industry depending particularly on high power density and reliability.Energy saving and emission reduction of diesel engines can remarkably contribute to national security and environmental protection.However,the introduction of spray injection pressure has restricted the performance of diesel engines in recent years.The reason is that the spray impingement can concurrently increase soot emission subjected to a prolonged combustion period.Therefore,a wall-flow-guided combustion system was developed to greatly apply for many products using the fuel momentum produced by the high injection pressure.Deutz’s TCD2015(T for turbocharger,C for charge air cooling,and D for diesel particle filter)type engine is one of the typical diesel engines with a wall-flow-guided combustion system.The TCD combustion system is characterized by a shallow basin to form the circular ridge,especially for high performance and emission reduction.Current similar combustion system also appears in many types of engine with a prominent ability.This study aims to explore the effect of the TCD combustion system on the combustion process and emission in a diesel engine.A single-cylinder diesel engine experiment was performed at different speeds,loads,and excess air coefficients(φ).Test results showed that the brake specific fuel consumption(BSFC)and the soot emission of the TCD combustion system were lower than those of the conventionalωcombustion system at different operation conditions.The BSFC drop tended to be the maximum of 7.01%at 1800 r/min,φ=1.2 operation.The maximum drop of 86.67%on soot emission appeared at 1800 r/min,and the brake power of 54 kW.Furthermore,the TCD combustion system outperformed at a low excess air coefficients between 1.2 to 1.6.A diesel engine simulation model was also built in AVL Fire to reveal the improvement mechanism of fuel-air-mixing quality in the TCD combustion system.The simulation model configured k-ζ-f turbulence,wave spray breakup,Dukowicz spray evaporation,and ECFM-3Z combustion model.A verification for mesh size independence confirmed the unit size around 1mm.The spray total penetration(including vapor phase),in-cylinder pressure,and heat release rate were evaluated to ensure the accuracy of simulation in spray liquid penetration.The operations at 1800 r/min with different loads and excess air coefficients were chosen to evaluate the TCD combustion system performance.Simulation results for equivalent ratio distributions showed that the cyclic ridge formed the fuel stream towards the inner and outer chambers,and then guided the fuel diffusion towards the combustion chamber center and the cylinder head,where the shallow basin wall became the fuel guider to avoid fuel gathering in the clearance at 28°CA.The velocity distributions demonstrated that a smaller region of low-velocity presented in the TCD combustion system,compared with theωcombustion system,indicating smaller collision energy loss and better fuel-air-mixing quality.A better performance was achieved at the brake power of 72 kW andφ=1.2 operations,due to the faster spray motion.The fuel mass ratios in four equivalence ratio intervals were smaller than 1,1-2,2-4,and larger than 4,further to evaluate the fuel-air-mixing quality in the cylinder.Results showed that the fuel mass ratios of TCD combustion system in the equivalence ratio 2-4 and larger than 4 were smaller than those ofωcombustion system in 0-30°CA with a maximum of 9.75%atφ=1.2 operation,while in 30-60°CA the fuel mass ratios in the equivalence ratio smaller than 1 and 1-2 were larger with 7.45%the maximum drop at the brake power of 72 kW.Hence,the great performance of the TCD combustion system relied mainly on the sufficient fuel-air-mixing facilitated by the chamber structure.The finding can provide a sound technical reference for the development and optimization of the combustion system in diesel engines.
作者 康与宁 李向荣 薄大伟 陈彦林 刘栋 常江 Kang Yuning;Li Xiangrong;Bo Dawei;Chen Yanlin;Liu Dong;Chang Jiang(School of Mechanical Engineering,Beijing Institute of Technology,Beijing 100081,China;Military Delegate Room of People’s Liberation Army Ground Force Armaments Department in Beijing Area,Beijing 100072,China)
出处 《农业工程学报》 EI CAS CSCD 北大核心 2021年第11期50-59,共10页 Transactions of the Chinese Society of Agricultural Engineering
基金 十三五重点计划项目(104010204)。
关键词 柴油机 试验 TCD燃烧系统 燃烧过程 排放特性 diesel engine experiments TCD combustion system combustion process emission characteristic
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