Your search keyword '"Qin, Dingyi"' showing total 2 results

1. A particle-tracking image pyrometer for characterizing ignition of pulverized coal particles.

Author

Chen, Qianyun, Qin, Dingyi, Li, Jing, and Liu, Zhaohui

Subjects

*PULVERIZED coal, *COAL combustion, *DIGITAL cameras, *PYROMETERS, *BITUMINOUS coal, *FLUE gases

Abstract

In this study, a particle-tracking image pyrometer (PTIP) system, based on a high-resolution high-speed camera and a digital single lens reflex (SLR) camera, was proposed to investigate the ignition characteristics of pulverized coal particles. The goal of the PTIP system was to obtain reliable simultaneous measurements of the velocity, diameter, and temperature of individual burning particles. A modified particle-tracking velocimetry (PTV) algorithm was developed to collect the image sequences of individual particles, and it could weed out defocused particles and other odd particles by low-frequency filtration. Moreover, a template matching method was adopted to distinguish particles undergoing different combustion states (homogeneous volatile combustion or heterogeneous coal/char combustion). The experimental validation was carried out under an O 2 /CO 2 atmosphere in an optically accessible flat flame-supported entrained flow reactor. Particles of Shenhua (SH) bituminous coal, in the size range of 70–133 μm, were combusted in the flue gas with gas temperature of 1400 K and O 2 concentration of 20%. The diameter-temperature patterns of particles along their trajectories were discussed. Several criteria based on statistical analysis were adopted to divide the combustion process and obtain the ignition delay time (IDT) and devolatilization duration time (DDT). • Speed, diameter and temperature of a burning particle are measured simultaneously. • Modified PTV method is used to capture the combustion sequence of single particle. • Different stages of particle combustion are distinguished by particle templates. • Statistical analysis is adopted to obtain characteristic time for combustion. • Combination of micro and macro photography improves the credibility of diagnosis. [ABSTRACT FROM AUTHOR]

Published

2022

2. Effects of Pressure and Coal Rank on the Oxy-Fuel Combustion of Pulverized Coal.

Author

Qin, Dingyi, Chen, Qianyun, Li, Jing, and Liu, Zhaohui

Subjects

*COAL combustion, *ANTHRACITE coal, *COMBUSTION, *BITUMINOUS coal, *COAL, *SINGLE-lens reflex cameras, *PULVERIZED coal, *COAL pyrolysis

Abstract

Pressurized oxy-fuel combustion technology is the second generation of oxy-fuel combustion technology and has low energy consumption and low cost. In this research, a visual pressurized flat-flame reaction system was designed. A particle-tracking image pyrometer (PTIP) system based on a high-speed camera and an SLR camera was proposed. Combining the experimental system and data-processing method developed, the ignition and combustion characteristics of a single coal particle between 69 and 133 μm in size were investigated. The results indicated that at atmospheric pressure, the ignition delay time of ShanXi (SX) anthracite coal was longer than that of ShenHua (SH) bituminous coal, while that of PRB sub-bituminous coal was the shortest. As the pressure rose, the ignition delay time of the PRB sub-bituminous coal and SX anthracite coal showed a continuous increasing trend, while the ignition delay time of SH bituminous coal showed a trend of first increasing and then decreasing. Moreover, pressure also affects the pyrolysis process of coal. As the pressure increases, it became more difficult to release the volatiles produced by coal pyrolysis, which reduced the release rate of volatiles during the ignition stage, and prolonged the release time and burning duration time of volatiles. [ABSTRACT FROM AUTHOR]

Published

2022