Abstract
<p>We adopt <a href="http://dict.cnki.net/dict_result.aspx?searchword=%e6%b2%89%e6%b7%80%e6%b3%95&amp;tjType=sentence&amp;style=&amp;t=precipitation">precipitation</a> to prepare the nanometer CuO and coat it on boron particles of micro- and nano-size. The <a href="http://dict.cnki.net/dict_result.aspx?searchword=%e5%bd%a2%e8%b2%8c&amp;tjType=sentence&amp;style=&amp;t=morphology">morphology</a> and coating result of B/CuO nanocomposite thermite were characterized using different techniques, such as scanning electron microscopy, X-ray diffraction, and energy-dispersive X-ray spectroscopy. The results indicated that the boron particles were coated completely by nanocomposite CuO and well distributed. The B/CuO nanocomposite thermite reaction process was tested by thermogravimetric/differential scanning calorimetry. The obtained reaction temperature of B/CuO particles is about 116.86° lower than that of boron particles. The B/CuO thermite and boron powder were added to Mg/PTFE propellant to be measured for their respective combustion performance. The results showed that the B/CuO-Mg/PTFE propellant burning rate increased by 12.87%, mass burning rate by 13.48%, and combustion temperature increased by 56.3° compared to the B-Mg/PTFE propellant. The above results indicate that the CuO coating of boron particles increases the combustion performance of propellant compared with uncoated particles.</p>
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