爆破器材
爆破器材
폭파기재
2014年
5期
21-25
,共5页
丁玉奎%吴翼%王海丹%刘国庆%姬文苏
丁玉奎%吳翼%王海丹%劉國慶%姬文囌
정옥규%오익%왕해단%류국경%희문소
黑梯炸药%热分解%差示扫描量热法%熔化峰
黑梯炸藥%熱分解%差示掃描量熱法%鎔化峰
흑제작약%열분해%차시소묘량열법%용화봉
TNT-RDX explosive%thermal decomposition%DSC%melting peak
针对部分黑梯炸药的 DSC 曲线无 RDX 熔化峰的情况,通过分析不同升温速率下单质 RDX 的 DSC 曲线,确定有利于黑梯炸药 DSC 曲线出现 RDX 熔化峰的测试条件。并将 TNT 和 RDX 以质量比为3︰7和4︰6的比例溶解在丙酮中,重结晶制成黑梯炸药,用 DSC 对其进行热分析,通过改变 DSC 测试条件出现了 RDX 的熔化峰。分析认为,部分 RDX 在熔融 TNT 中溶解后,液相 RDX 以自催化的方式分解,分解峰左移,峰温降低,对熔化峰进行了掩盖。对样品的热分解动力学和热力学参数进行计算和对比之后发现,黑梯炸药的活化能比 RDX 增加了6.02%,热爆炸临界温度提高了2.08℃,热力学参数发生了变化,说明 TNT 和 RDX 通过氢键相互作用,提高了RDX 的热稳定性, RDX 的使用安全性有一定改善。
針對部分黑梯炸藥的 DSC 麯線無 RDX 鎔化峰的情況,通過分析不同升溫速率下單質 RDX 的 DSC 麯線,確定有利于黑梯炸藥 DSC 麯線齣現 RDX 鎔化峰的測試條件。併將 TNT 和 RDX 以質量比為3︰7和4︰6的比例溶解在丙酮中,重結晶製成黑梯炸藥,用 DSC 對其進行熱分析,通過改變 DSC 測試條件齣現瞭 RDX 的鎔化峰。分析認為,部分 RDX 在鎔融 TNT 中溶解後,液相 RDX 以自催化的方式分解,分解峰左移,峰溫降低,對鎔化峰進行瞭掩蓋。對樣品的熱分解動力學和熱力學參數進行計算和對比之後髮現,黑梯炸藥的活化能比 RDX 增加瞭6.02%,熱爆炸臨界溫度提高瞭2.08℃,熱力學參數髮生瞭變化,說明 TNT 和 RDX 通過氫鍵相互作用,提高瞭RDX 的熱穩定性, RDX 的使用安全性有一定改善。
침대부분흑제작약적 DSC 곡선무 RDX 용화봉적정황,통과분석불동승온속솔하단질 RDX 적 DSC 곡선,학정유리우흑제작약 DSC 곡선출현 RDX 용화봉적측시조건。병장 TNT 화 RDX 이질량비위3︰7화4︰6적비례용해재병동중,중결정제성흑제작약,용 DSC 대기진행열분석,통과개변 DSC 측시조건출현료 RDX 적용화봉。분석인위,부분 RDX 재용융 TNT 중용해후,액상 RDX 이자최화적방식분해,분해봉좌이,봉온강저,대용화봉진행료엄개。대양품적열분해동역학화열역학삼수진행계산화대비지후발현,흑제작약적활화능비 RDX 증가료6.02%,열폭작림계온도제고료2.08℃,열역학삼수발생료변화,설명 TNT 화 RDX 통과경건상호작용,제고료RDX 적열은정성, RDX 적사용안전성유일정개선。
To clarify the reasons for the disappearance of RDX melting peak DSC on the curves of some TNT-RDX explosives, DSC curves of RDX at different heating rates were analyzed to find out the experimental conditions under which the melting peak will present. TNT and RDX with mass ratios of 3︰7 and 4︰6 were dissolved in acetone and recrystallized to get TNT-RDX explosives. The TNT-RDX explosives were tested by DSC, and RDX melting peak can be observed at cer-tain testing conditions. The analysis shows that the desolvation of part of RDX in fusion TNT leads to the decomposition of liquid RDX in a self-catalysis way and left shift of decomposition peak toward to lower temperature area overlapping with the melting peak. Decomposition kinetics and thermodynamics of samples were calculated and compared. The results show that the activation energy of TNT-RDX explosive is 6. 02% higher than RDX, and the critical exploding temperature increases by 2. 08 ℃ . Thermodynamics have also changed showing that TNT can improve the heat stability and security use of RDX by interaction with RDX trough hydrogen bond.
