Experimental and numerical study of coal dust ignition by a hot particle

Experimental and numerical study of coal dust ignition by a hot particle

[Display omitted] •Hot small-sized metal particle ignites a layer of coal dust.•The ignition characteristics were determined from the experiments.•The mathematical model was developed to forecast the ignition characteristics.•The model describes the experimental results well.•Limitations were analyz...

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Bibliographic Details
Published in:Applied thermal engineering Vol. 133; pp. 774 - 784
Main Authors: Glushkov, Dmitrii O., Kuznetsov, Geniy V., Strizhak, Pavel A.
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 25-03-2018
Elsevier BV
Subjects:
Boilers
Chemical reactions
Coal dust
Coal mines
Computer simulation
Delay
Dust
Fire prevention
Fire protection
Flammability
Hot particle
Ignition
Layer of coal dust
Lignite
Mass transfer
Mathematical model
Mathematical models
Metal particles
Organic chemistry
Particle size
Safety management
Solid fuels
Spontaneous combustion
Volatile compounds
Hot particle
Layer of coal dust
Mathematical model
Ignition
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Summary:[Display omitted] •Hot small-sized metal particle ignites a layer of coal dust.•The ignition characteristics were determined from the experiments.•The mathematical model was developed to forecast the ignition characteristics.•The model describes the experimental results well.•Limitations were analyzed for the practical use of the predictive mathematical model. This work studies the ignition of a layer of brown coal dust by hot metal particles experimentally and numerically. The experiments establish the limits of the flaming ignition of gas and ignition delay times when the parameters of solid fuel and metal particles varied in a wide range. The particle size of coal ranged from 0.1 to 1 mm; the shapes of the metal particles were sphere, disk, and cube; their initial temperature varied between 1000 and 1400 K. A mathematical model was developed for describing the processes involved in heat and mass transfer as well as chemical reactions around the local heat source. The results of the numerical simulation are in good agreement with the experimental data: boundaries of the flaming ignition of coal; coal ignition delay times; three modes of flaming ignition of coal with the ignition zone of volatiles located in the vicinity of the hot particle. The mathematical model is good at predicting the ignition conditions during interaction between a hot metal particle and a layer of coal dust. The model can also be used for developing the promising technology of steam boiler start-up by highly reactive coal instead of flammable liquid combustion. Another application is the development of fire prevention guidelines for tightening fire safety management at productions deal with coal mining, transportation, storage, processing, and combustion. Finally, the paper includes the analysis of limitations for the practical use of the predictive mathematical model in thermal power engineering and fire safety management.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2018.01.049