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International Journal of Automotive Technology > Volume 22(2); 2021 > Article
International Journal of Automotive Technology 2021;22(2): 455-463.
doi: https://doi.org/10.1007/s12239-021-0042-2
SOOT DEVELOPMENT IN AN OPTICAL DIRECT INJECTION SPARK IGNITION ENGINE FUELED WITH ISOOCTANE
Fangxi Xie 1, Miaomiao Zhang 2, Yongzhen Wang 1, Yan Su 1, Wei Hong 1, Peng Cheng 1
1Jilin University
2Jiangsu Normal University
PDF Links Corresponding Author.  Yan Su  , Email. suyan@jlu.edu.cn
ABSTRACT
To better understand the formation and evolution processes of soot, the two-color laser induced incandescence diagnostic method was applied on a single cylinder optical direct injection spark ignition engine. Soot volume fraction was measured, and soot distribution was imaged as cyclic fuel quantity changes. The results show that 45.5 mg/cycle generates the most soot at the same measure plane. Pool fire dominates the formation of soot in the tested engine and generates more soot on the top surface of the piston near the injector. In-cylinder soot increases until 42°CA ATDC and then reduces due to oxidation. Pool fire continues through the expansion stroke till 52°CA ATDC, and then soot cloud gathers near the 10 mm plane. After 82°CA ATDC, in-cylinder soot basically in equilibrium, and residual soot moves follow the in-cylinder flow randomly and evenly distributes within the whole combustion chamber. With increasing cyclic fuel quantity, particles number concentration gradually increases and their distribution present dual-peak shape. In detail, 45.5 mg/cycle emits the most accumulation mode particles while 52 mg/cycle emits the most nucleation mode particles.
Key Words: Soot, Laser induced incandescence, 2-Colour, GDI engine, Particles

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