This work aimed to study the potential use of pyrolyzed orange peels as solid biofuels and biosorption of heavy metals. The dry biomass and the biofuel showed moderate levels of carbon (44-62%), high levels of oxygen (30-47%), lower levels of hydrogen (3-6%), nitrogen (1-2.6%), sulfur (0.4-0.8%) and ash with a maximum of 7.8%. The activation energy was calculated using Kissinger method, involving a 3 step process: volatilization of water, biomass degradation and volatilization of the degradation products. The calorific value obtained was 19.3MJ/kg. The studies of metal biosorption based on the Langmuir model obtained the best possible data fits. The results obtained in this work indicated that the potential use of waste orange peel as a biosorbent and as a solid biofuel are feasible, this product could be used in industrial processes, favoring the world economy.
In order to minimize environmental problems related to the generation and disposal of spent mushroom substrate (SMS) from mushroom cultivation activities, this study aimed to evaluate the thermal behaviour of the spent shiitake substrate (SSS) and its resulting biochar. Analyzing biochars produced at a temperature of 350 °C (BC350) was found to be that with the highest energy potential due to a reduced amount of resulting ash and nitrogen, and larger amounts of carbon, hydrogen, fixed carbon, as well as a higher calorific value, gravimetric yield, and gravimetric yield factor. SSS and BC350 were used in thermogravimetric and kinetic analyses. Thermogravimetric analyses were carried out at three heating rates, 10, 15, and 20 °C/min in an oxidizing atmosphere. Conversion steps relating to water loss and degradation of hemicellulose, cellulose, and lignin have been identified. The kinetic study was carried out by non‐isothermal and non‐isoconversional Kissinger method. The activation energies obtained were 110 and 136 kJ · mol−1 for the SSS and BC350, respectively, and are well within the range found for other lignocellulosic materials, such as bagasse and wheat straw. The pre‐exponential factor, in the order of 108, indicated the presence of complex elements.
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