Abstract
This study focuses on the development of new methodological approaches to dust-preparation and burning of separated particles, including through the use of polyfractional ensembles. Coal dust screening by means of sieve analysis is described in standard methods. However, in order to further use the results obtained during mathematical modeling of particle motion in fuel-air mixture and exothermal reactions of oxidation while burning in a torch, it must be possible to differentiate and integrate continuous functions. The methodology is based on the continuity of particle motion in a mixture with air in the calculation of aerodynamic and heat-mass exchange processes in a torch. The paper employs new scientific approaches to transforming and normalizing a continuously differentiable function described by the Gauss curve. We propose to combine mathematical modeling of such functions with methods of approximation of piece-linear functions developed by Professor S. V. Aliukov. The implementation of such methods helps reduce calculation errors of particle size and deviations thereof from average equivalent diameter and to avoid the Gibbs effect while differentiating. The paper contains analytical calculations based on the proposed method and experimental data. Quantitative and qualitative results of comparing analytical and experimental data are also presented. We provide recommendations on the further use and extension of the range of the results obtained in a computer simulation of fuel production and burning processes in a torch.
Highlights
We developed and implemented a method of mathematical modeling based on new approaches to approximation of piece-linear functions
The lower limit of integration is defined by means of the fractional composition of fuel particles in the range of small values δ and is of great importance for calculating the igniting processes of the fuel–air mixture, whereas the upper limit is connected with the calculation of fuel under-burning with the given length of a torch, or with the definition of the necessary length of a torch under given under-burning of fuel, which is connected with the fractional composition of fuel in the range of large values δ
The conclusions presented correspond to the scientific objectives of the study, namely: the standard function of coal dust screening through sieve analysis is transformed into a continuously differentiable function which makes it applicable for the mathematical modeling of the ignition of coal particles in an ensemble
Summary
Information about Developments in the Scientific Field of Coal Dust Sieving and Its. Scientists around the world have studied the processes of burning and producing solid fuel. The most comprehensive overview of the preparation of coal dust at thermal power stations can be found in [1]. One of the main conditions for effective and highquality burning of solid fuel is taking its polyfractional composition into account, which can be confirmed by mathematical models presented in [2]. The presence of a sufficient amount of oxygen as an oxidizing agent and the fineness of grinding are mentioned in [3]. There are various models of burning [4], screening, and preparing solid fuel [1,5]
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