4.7 Article

Product-oriented thermodynamic function construction of wheat straw and thermodynamic analysis for rapid pyrolysis

Journal

FUEL
Volume 358, Issue -, Pages -

Publisher

ELSEVIER SCI LTD
DOI: 10.1016/j.fuel.2023.130285

Keywords

Wheat straw; Fast pyrolysis; Thermodynamic function; Reaction feasible region

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This study determined the conditions for product regulation of wheat straw pyrolysis through thermodynamic analysis. By constructing reactions, high-value components were produced. The results showed that temperature favored spontaneous endothermic reactions, while pressure did not. By adjusting temperature and pressure, the production process of the product could be controlled.
Given the complexity of the rapid pyrolysis reaction system of wheat straw and the difficulty in product regulation, this paper investigated the feasible range for high-value product formation. It determined the conditions for product regulation of wheat straw pyrolysis through thermodynamic analysis. The research constructed the standard enthalpy of formation Delta llf0, standard entropy Delta S0m, and standard Gibbs free energy of formation Delta G0f of wheat straw molecules. Based on the pyrolysis characteristics of cellulose, hemicellulose, and lignin, which were the main components of wheat straw, 34 reactions were constructed to produce high-valued components such as 2-furfural, acetone, and guaiacol. With Gibbs free energy and equilibrium constant as evaluation indexes, the relationship between the feasible region of the reaction and temperature and pressure at 200-800 degrees C and 0.1-10 MPa was explored. The results showed that Delta ll0f was-115.86 kJ mol-1, Delta S0m was 66.34 J mol-1 K-1 and Delta G0f was -135.64 kJ mol-1. The temperature was conducive to a spontaneous endothermic reaction, whereas pressure was not conducive to a spontaneous reaction. As the pressure increases, the temperature required for spontaneous reaction also increases. At 10 MPa, the thermodynamic temperature at which the reaction of glyoxal and acrolein could proceed spontaneously was increased by 318 degrees C and 87 degrees C, respectively. At 0.5 MPa, the range of 3-hydroxy -2-butanone could be spontaneous was 200-388 degrees C. By adjusting the temperature and pressure, the product's production process could be directed.

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