Modeling of destruction processes during recycling of rubber-technical waste using the technology of multi-contour circulation pyrolysis

Authors

DOI:

https://doi.org/10.15587/1729-4061.2017.101725

Keywords:

thermal destruction, recycling of rubber-technical wastes, material balance, concentration of vapor and gas mixture

Abstract

We performed modeling of the processes of destruction during recycling of rubber-technical waste in line with the technology of multi-contour circulation pyrolysis. The purpose of the present study is to develop a mathematical model for the process of thermal recycling of rubber-technical waste in line with the technology of multi-contour circulation pyrolysis.

We developed a scheme of destructive transformations of the starting mass of waste, taking into account kinetics of the process of thermal decomposition of rubber and material flows of the formed phases in the equipment.

We constructed a mathematical model of kinetic regularities and of the rate of destruction of rubber-technical waste depending on the concentration of original and resulting components. Kinetic parameters and the reaction rate are used for subsequent modeling of the recycling process and for determining the end products of waste decomposition.

Result of present research and theoretical modeling is the calculations of the concentration of gaseous and condensed substances – products of thermal decomposition of the original mass of waste, formed in the range of 450–600 °С.

Application of the given model is necessary when optimizing temperature modes of the equipment. The use of the model might be promising while creating industrial plants with a set productivity. It could also provide the possibility of recycling of different types of organic waste and their mixtures in line with the technology of multi-contour circulation pyrolysis.

Modeling that was performed justifies the reasons and foundations to control the process of repeated condensation and recirculation of heavy condensed flows of vapor and gas mixture. Therefore, if one knows the original composition of vapor and gas mixture from the reactor, it is possible to optimize cooling temperatures in contours to obtain the end product of required quality.

Author Biographies

Serhiy Ryzhkov, Admiral Makarov National University of Shipbuilding Heroiv Stalinhrada ave., 9, Mykolaiv, Ukraine, 54025

Doctor of Technical Sciences, Professor, Rector

Department of Ecology and Environmental Technologies

Lyudmila Markina, Admiral Makarov National University of Shipbuilding Heroiv Stalinhrada ave., 9, Mykolaiv, Ukraine, 54025

PhD, Associate Professor

Department of Ecology and Environmental Technologies

Marharyta Kryva, Admiral Makarov National University of Shipbuilding Heroiv Stalinhrada ave., 9, Mykolaiv, Ukraine, 54025

Department of Ecology and Environmental Technologies

References

  1. Markina, L. M. (2008). Modeling research of processing organic waste by multicircuit circulatory pyrolysis obtaining alternative fuels. Collection of Scientific Publications NUS, 4, 101–109.
  2. Osayi, J. I., Iyuke, S., Ogbeide, S. E. (2014). Biocrude Production through Pyrolysis of Used Tyres. Journal of Catalysts, 2014, 1–9. doi: 10.1155/2014/386371
  3. Ani, F. N., Mat Nor, N. S. (2012). Microwave induced fast pyrolysis of scrap rubber tires. AIP Conference Proceedings, 1440 (1), 834–841. doi: 10.1063/1.4704294
  4. Rofiqul Islam, M., Parveen, M., Haniu, H., Islam Sarker, M. R. (2010). Innovation in Pyrolysis Technology for Management of Scrap Tire: a Solution of Energyand Environment. International Journal of Environmental Science and Development, 1 (1), 89–96. doi: 10.7763/ijesd.2010.v1.18
  5. Zhang, X., Wang, T., Ma, L., Chang, J. (2008). Vacuum pyrolysis of waste tires with basic additives. Waste Management, 28 (11), 2301–2310. doi: 10.1016/j.wasman.2007.10.009
  6. Islam, M. N., Nahian, M. R. (2016). Improvement of Waste Tire Pyrolysis Oil and Performance Test with Diesel in CI Engine. Journal of Renewable Energy, 2016, 1–8. doi: 10.1155/2016/5137247
  7. Kalitko, V. A. (2010). Steam thermolysis of tire shreds: modernization in afterburning of accompanying gas with waste steam. Journal of Engineering Physics and Thermophysics, 83 (1), 179–187. doi: 10.1007/s10891-010-0333-3
  8. Kalitko, U. (2012). Waste Tire Pyrolysis Recycling with Steaming: Heat-Mass Balances & Engineering Solutions for By-Products Quality. Material Recycling – Trends and Perspectives. doi: 10.5772/31535
  9. Brems, A., Baeyens, J., Vandecasteele, C., Dewil, R. (2011). Polymeric Cracking of Waste Polyethylene Terephthalate to Chemicals and Energy. Journal of the Air & Waste Management Association, 61 (7), 721–731. doi: 10.3155/1047-3289.61.7.721
  10. Zaitseva, T. A. (2010). The landfill for solid domestic waste (tbo) is an anthropogenic ecological system. Research and Innovation, 4, 35–43.
  11. Ryzhkov, S. S., Markina, L. M., Kryva, M. S., Hlyniana, V. V. (2015). Analysis of the main thermodynamic parameters of multistage circulation pyrolysis of organic waste. Collection of Scientific Publications NUS, 4, 104–112. doi: 10.15589/jnn20150415
  12. Ryzhkov, S. S., Markina, L. M., Kryva, M. S. (2012). Features analysis of physical and chemical processes of multicircuit circulatory pyrolysis of organic waste. Collection of Scientific Publications NUS, 5-6, 125–131.
  13. Aisien, F. A., Ebewele, R. O., Hymore, F. K. (2011). Mathematical Model of Sorption Kinetics of Crude Oil by Rubber Particles from Scrap Tyres. Leonardo Journal of Sciences, 18, 85–96. Available at: http://ljs.academicdirect.org/A18/085_096.pdf
  14. Ryzhkov, S. S., Markina, L. M., Kryva, M. S. (2013). Research of kinetics of thermal destraction of organic waste. Ecological safety, 2, 82–88.

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Published

2017-06-22

How to Cite

Ryzhkov, S., Markina, L., & Kryva, M. (2017). Modeling of destruction processes during recycling of rubber-technical waste using the technology of multi-contour circulation pyrolysis. Eastern-European Journal of Enterprise Technologies, 3(10 (87), 28–35. https://doi.org/10.15587/1729-4061.2017.101725