天津大学学报
天津大學學報
천진대학학보
JOURNAL OF TIANJIN UNIVERSITY SCIENCE AND TECHNOLOGY
2014年
10期
892-897
,共6页
裴毅强%张建业%秦静%李翔%代玉利%李云龙
裴毅彊%張建業%秦靜%李翔%代玉利%李雲龍
배의강%장건업%진정%리상%대옥리%리운룡
GDI汽油机%缸内压力%放热率%微粒
GDI汽油機%缸內壓力%放熱率%微粒
GDI기유궤%항내압력%방열솔%미립
gasoline direct injection engine%cylinder pressure%heat release rate%particulate
在一台增压直喷(GDI)汽油机上,使用快速微粒光谱仪(DMS500)对排气中微粒排放分布进行了实验研究.结果表明:在发动机起动后数秒内微粒排放较高,随着暖机进行积聚态微粒排放减少,热机怠速工况排气微粒主要以核模态为主.随着过量空气系数λ减小缸内峰值压力增加,燃烧持续期缩短,缸内平均温度升高,燃烧后期缸内温度下降幅度增加,混合气氧含量降低,这些均促进了碳烟排放.采用稀混合气时,循环变动升高.低负荷时,积聚态微粒对λ变化较敏感;增加负荷和转速后,积聚态微粒数浓度有所降低,表现为随λ减小而增加的趋势.采用浓混合气时,排气微粒质量迅速增加.在实验工况,排气微粒的几何平均直径(GMD)和中位直径(CMD)基本在10,nm以内,λ为0.8时微粒的GMD和CMD值较大.
在一檯增壓直噴(GDI)汽油機上,使用快速微粒光譜儀(DMS500)對排氣中微粒排放分佈進行瞭實驗研究.結果錶明:在髮動機起動後數秒內微粒排放較高,隨著暖機進行積聚態微粒排放減少,熱機怠速工況排氣微粒主要以覈模態為主.隨著過量空氣繫數λ減小缸內峰值壓力增加,燃燒持續期縮短,缸內平均溫度升高,燃燒後期缸內溫度下降幅度增加,混閤氣氧含量降低,這些均促進瞭碳煙排放.採用稀混閤氣時,循環變動升高.低負荷時,積聚態微粒對λ變化較敏感;增加負荷和轉速後,積聚態微粒數濃度有所降低,錶現為隨λ減小而增加的趨勢.採用濃混閤氣時,排氣微粒質量迅速增加.在實驗工況,排氣微粒的幾何平均直徑(GMD)和中位直徑(CMD)基本在10,nm以內,λ為0.8時微粒的GMD和CMD值較大.
재일태증압직분(GDI)기유궤상,사용쾌속미립광보의(DMS500)대배기중미립배방분포진행료실험연구.결과표명:재발동궤기동후수초내미립배방교고,수착난궤진행적취태미립배방감소,열궤태속공황배기미립주요이핵모태위주.수착과량공기계수λ감소항내봉치압력증가,연소지속기축단,항내평균온도승고,연소후기항내온도하강폭도증가,혼합기양함량강저,저사균촉진료탄연배방.채용희혼합기시,순배변동승고.저부하시,적취태미립대λ변화교민감;증가부하화전속후,적취태미립수농도유소강저,표현위수λ감소이증가적추세.채용농혼합기시,배기미립질량신속증가.재실험공황,배기미립적궤하평균직경(GMD)화중위직경(CMD)기본재10,nm이내,λ위0.8시미립적GMD화CMD치교대.
This is an experimental research on the distribution of particulate emissions in the exhaust gas of a turbo-charged gasoline direct injection(GDI) engine by using a fast particle spectrometer (DMS500). The results showed high particulate emissions within a few seconds after startup. As the machine continued to warm up, the accumulation mode particulate emissions reduced. In hot idling condition, nucleation mode particulates were the dominant exhaust particulates . With the excess air ratio reduced, the peak cylinder pressure increased, the combustion duration short-ened, the average temperature inside the cylinder gradually increased, post-combustion cylinder temperature decreased and the oxygen content in the mixture lowered, which were conducive to soot formation and elevated cyclic variations when using lean gas. At low load, the accumulation mode particulates were sensitive to the change of the excess air ratio. After we increased load and speed, concentrations of accumulation mode particles decreased, which was demon-strated by the decreasing excess air ratio and increasing concentrations of accumulation mode particles. When using concentrated mixture, exhaust particulate mass rapidly increased. In the experimental conditions, the geometric mean diameter (GMD) and count median diameter (CMD) of exhaust gas particles were basically less than 10 nm. When the excess air ratio is 0.8, the values of GMD and CMD particulates were comparatively large.