Development of a new method for obtaining claydite with a minimal thermal conductivity coefficient

Authors

DOI:

https://doi.org/10.15587/1729-4061.2017.101089

Keywords:

claydite, alumina, component of concrete mixtures, optimal thermal conductivity, pore formation, thermal treatment

Abstract

The object of study is the technology of creation of claydite with a minimal coefficient of thermal conductivity. Most problematic is the lack of methods for determining the optimal technological parameters of thermal treatment of raw materials to obtain claydite with a low coefficient of thermal conductivity. The reason for this is that the existing methods are aimed at creating mullite during roasting of the alumina raw materials, as a substance of sufficient strength. Although, when claydite is used as a thermal insulation filling or as an additive to a concrete mixture, a reduction in the coefficient of thermal conductivity in the formation of the structure of claydite is more significant than the strength value. In the course of research, we created a number of experimental samples of claydite at different initial factors. Fire resistance was determined by comparing the behavior of the examined and standard samples when heated. Bulk thermal conductivity was determined by the thermal conductivity meter ITP-MG4 made by SKB Stroypribor, Russia. Strength of the material was determined by the Rockwell method.

To determine the optimal technological parameters for the production of claydite from the specified alumina mixture, we used the method of experiment planning and the optimization of the resulting equation employing the Lagrange method with the Kuhn–Tucker conditions. Based on data received, the technology of obtaining claydite with improved thermal-physical properties is as follows. Clay mixture is dried to humidity of 38 % and the granules are formed (by pressing a grid with a cell of 6×20 mm). Next, the pallet with granules is put into a heating furnace for 15 minutes at 270 °C. After the heating furnace, the granules are discharged into a drum furnace, where they are roasted at temperature 1250 °C for 1.5 hours.

The results obtained make it possible to reduce the coefficient of thermal conductivity of claydite by 2.25 times. The applied technique could be used for future studies of samples with different additives, including industrial waste. This in turn will allow a more effective use of available raw materials as well as reduction in the cost of product.

Author Biographies

Anatoliy Pavlenko, Kielce University of Technology Tysiacholittia panstva Polskoho str., 7, Kielce, Poland, 25-314

Doctor of Technical Sciences, Professor

Department of Building Physics and Renewable Energy

Andrii Cheilytko, Zaporizhzhya State Engineering Academy Soborny ave., 226, Zaporizhzhya, Ukraine, 69006

PhD, Associate Professor

Department of heating energy

Oleksiy Lymarenko, Poltava National Technical Yuri Kondratyuk University Pershotravnevyi ave., 24, Poltava, Ukraine, 36011

Postgraduate student

Department of heat, ventilation and heat

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Published

2017-06-08

How to Cite

Pavlenko, A., Cheilytko, A., Lymarenko, O., & Taranenko, O. (2017). Development of a new method for obtaining claydite with a minimal thermal conductivity coefficient. Eastern-European Journal of Enterprise Technologies, 3(1 (87), 11–16. https://doi.org/10.15587/1729-4061.2017.101089

Issue

Vol. 3 No. 1 (87) (2017): Engineering technological systems

Section

Engineering technological systems

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Copyright (c) 2017 Anatoliy Pavlenko, Andrii Cheilytko, Oleksiy Lymarenko, Olesia Taranenko

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