To comprehensively understand soot formation in flames of liquid fuel, the soot primary particle size (PPS) in n-heptaneair diffusion flame at pressures up to 5 bar was investigated in this work. A series of experiments were conducted in a high-pressure laminar flame burner system, and the spatial distributions of soot primary particle size in the flames at atmospheric and elevated pressures were evaluated by two-dimensional Time-Resolved Laser-Induced Incandescence (TiRe-LII). The results indicated a tendency that the conunt mean diameter (D-p,D-mean) of soot primary particle increased with enhancing laser fluence, which might be attributed to inaccuracy of the thermal accommodation coefficient at the increasing laser fluences. The spatial distribution of D-p,D-mean varied with pressures. Further, the evolution of D-p,D-mean along the centerline and the radial distribution of D-p,D-mean at the pressures of 1.0-3.0 bar were also presented. The zone of the maximum D-p,D-mean moved from the flame centerline to the flame edge as the pressure increases. The spatial distribution of D-p,D-mean at 3.5-5.0 bar showed the area of maximum D-p,D-mean located at the annular wing region in flames and being floated as the pressure increased. This study complemented the existing theoretical knowledge of spatial primary particle size distribution (PPSD) in n-heptane laminar diffusion flames. (C) 2021 The Combustion Institute. Published by Elsevier Inc. All rights reserved.
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