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Lesnoy Zhurnal

Heat and Mass Transfer Simulation in the Pyrolysis Zone

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А.V. Safina, N.F. Timerbaev, D.F. Ziatdinova, R.G. Safin, A.R. Khabibullina

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Nowadays, about 200 mln m3 of timber is harvested in our country. At all stages of the process (from harvesting to raw wood processing) a large amount of waste that does not find any usage and has negative influence on the environment is generated at the same time. Pyrolysis is one of the feasible directions of such waste processing. The yield of pyrolysis products depends on the external conditions and the raw materials properties. The article describes a plant targeting for production of activated carbon from wood chips. The plant is designed as a mine. It has a pyrolysis zone operating in periodic mode. Heating elements are located in the lower part of the pyrolysis zone. They heat industrial chips prior to intense exothermic reactions. Thermal energy is transferred to the heating elements by a heat pipe placed in charcoal after the activation stage, which has temperature about 800 °C. Valuable products are obtained from wood waste with the use of this plant, which are in a great demand in the industry. The environmental problem of many wood processing enterprises is being solved; disposal of waste dumps. Mathematical model of the process has been devel-oped based on the analysis of the physical phenomenon and pyrolysis process formalization in the activated carbon plant. The model allows calculating the total time spent on wood waste processing and the main design parameters of the plant.


А.V. Safina, Candidate of Engineering Sciences, Associate Professor 
N.F. Timerbaev, Doctor of Engineering Sciences, Professor 
D.F. Ziatdinova, Doctor of Engineering Sciences, Professor 
R.G. Safin, Doctor of Engineering Sciences, Professor 
A.R. Khabibullina, Assistant 

Authors job

Kazan National Research Technological University, ul. K. Marksa, 68, Kazan, 420015, Russian Federation; e-mail:


mathematical model, heat and mass transfer, charcoal, pyrolysis, activation, gas flow

For citation

Safina А.V., Timerbaev N.F., Ziatdinova D.F., Safin R.G., Khabibullina A.R. Heat and Mass Transfer Simulation in the Pyrolysis Zone. Lesnoy Zhurnal [Forestry Journal], 2019, no. 1, pp. 153–160. DOI: 10.17238/issn0536-1036.2019.1.153


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Received on October 17, 2018

Heat and Mass Transfer Simulation in the Pyrolysis Zone