Effect of heating on the molecular carbon structure and the evolution of mechanical properties of briquette coal

Preparing briquette coal (BC) via the heating and pressure method can improve its low mechanical strength in physical simulation tests and gas outbursts while increasing experimental reliability. However, the influence of temperature on the mechanical properties of BC, microstructure, and the reasons underlying the evolution of mechanical strength of BC analyzed in terms of the carbon molecular structure of coal still need to be further studied. For this purpose, a rock mechanics test system, scanning electron microscopy, X-ray diffraction, and Fourier Transform Infrared Spectroscopy were used to analyze the optimum temperature for BC preparation and identify how the heating temperature affects the molecular carbon structure of BC to increase its strength. The result showed that as the temperature increases from 150 degrees C to 600 degrees C, the aromatic d(002) layer spacing decreased, whereas the aromatic layers of L-a and L-c increased, leading to an order degree increase of coal molecules. In addition, H-al/H and CH2/CH3 decreased, whereas A(ar)/A(al) increased, indicating that the aliphatic chains shortened and the aromaticity increased, ultimately improving the strength of BC. However, when the temperature exceeds 300 degrees C, the pores suffers damage, increasing the width of the pores and crack. Through uniaxial compression, the mechanical strength of BC first increases and then decreases. Moreover, the mechanical strength, Poisson's ratio, and elastic modulus at 300 degrees C were close to that of raw coal (RC). These results provide guidance to prepare excellent raw materials needed for large-scale physical simulation experiments to prevent and control coal and gas outbursts. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

The preparation of briquette coal at different temperatures can affect its mechanical strength and molecular structure, with higher temperatures improving strength but also causing damage to pores. These findings offer insights for preparing raw materials for large-scale physical simulation experiments on coal and gas outbursts.