Thermal Science 2024 OnLine-First Issue 00, Pages: 96-96
https://doi.org/10.2298/TSCI231221096S
Full text ( 804 KB)
Evaluation of thermochemical and kinetic characterisation of lignite and municipal solid waste and their blends for sustainable and clean conversion under TGa
Siddiqi Muhammad Hamid (School of Energy and Power Engineering, Xian Jiaotong University, Xian, China), hamidsiddiqi@stu.xjtu.edu.cn
Xiaomin Liu (School of Energy and Power Engineering, Xian Jiaotong University, Xian, China)
Ayub Salman (Centre for Energy Research and Development (CERAD), University of Engineering and Technology, Lahore, Punjab, Pakistan)
Naqvi Murawat Abbas (Department of Mechanical Engineering, NFC Institute of Engineering and Fertilizer Research, Faisalabad, Punjab, Pakistan)
Shafique Usman (Centre for Energy Research and Development (CERAD), University of Engineering and Technology, Lahore, Punjab, Pakistan)
Qureshi Tayyab (Centre for Energy Research and Development (CERAD), University of Engineering and Technology, Lahore, Punjab, Pakistan + Department of Technology, University of Lahore, Lahore, Punjab, Pakistan)
Iqbal Tanveer (Centre for Energy Research and Development (CERAD), University of Engineering and Technology, Lahore, Punjab, Pakistan)
With the expansion in generation of municipal solid waste (MSW) due to
population growth, and also increase the demand of clean energy production,
and the curb of land filling of MSW, it has established the need of our
society to use MSW with the available lignite under-the-vision of
waste-to-energy (WtE). WtE technique is an environment-friendly way for
disposing of MSW into the useful way globally. The thermal characteristics
of MSW with lignite and their blends were investigated to analyze thermal
stability. Blends of 10%, 20%, 30% and 50% of MSW with lignite were prepared
and tested in thermogravimetric analyzer from ambient to 1000°C under
heating-rate 10°C/min. This study revealed that steep in weight-loss
profiles in TG curves was reduced as MSW contents increased. It was
observed, MSW proportions in blends significantly affect the combustion
profiles and associated parameters like ignition temperature, weight-loss
and activation energy. The blends showed combustion properties of MSW and
lignite as maximum weight-loss occurred between the individual fuels.
Moreover, results indicated that with low proportion of MSW as 10% didn’t
significantly affect the combustion behavior and properties. While blend 30%
shows the more thermal stability than other samples. Thermal profiles of all
blended samples occurred in between of the parent samples. Results obtained
from experiment help to predict co-combustion thermal behavior of MSW and
lignite in existing facilities to generate clean-energy in sustainable way
from commercial power plants. The kinetic parameters obtained by
Horowitz-Metzger method showed improvement in ignition performance and find
the difference between blends.
Keywords: Municipal solid waste, Lignite, Waste to energy, Co-combustion, Thermogravimetric analysis