HTPB/AP界面脱粘破坏模式实验研究

2021 12th International Conference on Mechanical and Aerospace Engineering (ICMAE) Pub Date : 2021-07-16 DOI:10.1109/ICMAE52228.2021.9522528

J. Gong, Kai-li Ma, Jie Zhang, Zhengze Zhang, C. Bian, Guowei Zhu, N. Yan

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引用次数: 0

摘要

建立了复合固体推进剂的宏观和微观粘弹性力学模型。粘结能对复合固体推进剂的性能有重要影响。结果表明，随着粘结能的增大，推进剂的强度也随之增大。同时，采用描述脱粘过程的双线性黏聚区模型来模拟HTPB/AP界面的力学响应。根据黏结区模型，设计了单侧AP测试仪和夹芯仪，分别测定了粘结剂与AP之间的粘接能。基于夹层装置，无MAPO界面完全脱粘的单位面积粘接能等于14 J/m2，确定了有MAPO界面完全脱粘的单位面积粘接能下限。根据单侧AP的试验结果和宏细观力学粘弹性算法的数值模拟，可以得出复合固体推进剂中HTPB/AP的破坏模式为类似界面脱粘，而非完全界面脱粘。

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Experiment Study of Failure Mode of HTPB/AP Interfacial Debonding

Macro- and micro-mechanics viscoelastic model for composite solid propellant was proposed. The adhesive energy has an important influence on the behavior of composite solid propellant. It was shown that as the adhesive energy increases, the strength of propellant increases. Meanwhile, the mechanical response of HTPB/AP interface is modeled by the bilinear cohesive zone model describing the debonding process. According to the cohesive zone model, one-side AP tester and sandwich apparatus were designed to determine the value of adhesive energy between the binder and AP, respectively. Based on the sandwich apparatus, the energy per unit area of completely interfacial debonding without MAPO is equal to 14 J/m2, and lower limit of adhesive energy per unit area of completely interfacial debonding with MAPO is determined. According to the test result of one-side AP and the numerical simulation of macro- and micro-mechanics viscoelastic algorithm, it can conclude that the failure mode of HTPB/AP in composite solid propellant is the similarly interfacial debonding, instead of fully interfacial debonding.

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2021 12th International Conference on Mechanical and Aerospace Engineering (ICMAE)

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