约束条件下聚合物粘结炸药的压力依赖塑性模型

IF 0.7 4区工程技术 Q4 CHEMISTRY, APPLIED

Central European Journal of Energetic Materials Pub Date : 2021-09-30 DOI:10.22211/cejem/142512

Q. Wei, Xi-cheng Huang, Pengwan Chen, Rui Liu

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引用次数: 2

摘要

炸药的安全性与炸药的受力状态密切相关。在一定的应力刺激下，炸药可能会异常引爆。准确描述炸药的力学响应对炸药的安全性评价具有重要意义。聚合物粘结炸药（PBX）的力学性能在很大程度上取决于压力。在本研究中，研究了PBX在受限条件下的力学行为。研究发现，PBX在高围压下的应力-塑性应变响应是非线性和线性硬化部分的结合。然而，在表征PBX在这种压力下的机械行为时，线性硬化部分经常被忽略。应用卡拉戈齐和凯斯（K&C）模型来表征PBX的机械行为。数值结果表明，当围压较高时，由于损伤模型的局限性，K&C模型无法充分匹配实验数据。因此，通过考虑颗粒内损伤和穿颗粒损伤，建立了一种新的损伤模型。这种修改使得在原始K&C模型中引入线性硬化过程成为可能。描述高围压下应力-应变结果的方法是考虑应力-塑性-应变曲线，包括非线性和线性硬化部分。原始K&C模型和线性硬化模型的损伤演化分别应用于非线性和线性硬化部分。中欧高能材料杂志ISSN 1733-7178；e-ISSN 2353-1843版权所有©2021Łukasiewicz研究网络-波兰工业有机化学研究所340 Q.Wei，X.Huang，P.Chen，R.Liu，波兰在描述非线性硬化部分时，包括了线性硬化模型对原始K&C模型损伤演化的影响。模拟与实验结果的比较表明，改进的K&C模型能够很好地描述PBX在不同围压下的力学响应。

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A Pressure-Dependent Plasticity Model for Polymer Bonded Explosives under Confined Conditions

The safety of explosives is closely related to the stress state of the explosives. Under some stress stimulation, explosives may detonate abnormally. It is of great significance to accurately describe the mechanical response of explosives for the safety evaluation of explosives. The mechanical properties of polymer bonded explosives (PBXs) strongly depend on pressure. In this study, the mechanical behaviour of PBXs under confined conditions was investigated. It was found that the stress-plastic strain response of a PBX under high confining pressures is a combination of the non-linear and linear hardening portions. However, the linear hardening portion has often been neglected in characterizing the mechanical behaviour of a PBX under such pressures. The Karagozian and Case (K&C) model was applied to characterize the mechanical behaviour of PBXs. The numerical results demonstrated that when the confining pressure was high, the K&C model could not adequately match the experimental data due to the limitation of the damage model. Therefore, a new damage model was developed by means of considering intragranular damage and transgranular damage. This modification made it possible to introduce a linear hardening process into the original K&C model. The method proposed to describe the stress-strain results under high confining pressures was to consider the stress-plastic strain curve, including the nonlinear and linear hardening portions. The damage evolution of the original K&C model and a linear hardening model were applied for the nonlinear and linear hardening portions respectively. Central European Journal of Energetic Materials ISSN 1733-7178; e-ISSN 2353-1843 Copyright © 2021 Łukasiewicz Research Network – Institute of Industrial Organic Chemistry, Poland 340 Q. Wei, X. Huang, P. Chen, R. Liu Copyright © 2021 Łukasiewicz Research Network – Institute of Industrial Organic Chemistry, Poland The influence of the linear hardening model on the damage evolution of the original K&C model was included when describing the nonlinear hardening portion. A comparison between simulation and experiment showed that the modified K&C model could well describe the mechanical response of PBXs under different confining pressures.

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来源期刊

Central European Journal of Energetic Materials CHEMISTRY, APPLIED-ENGINEERING, CHEMICAL

CiteScore

1.80

自引率

25.00%

发文量

审稿时长

>12 weeks

期刊介绍： CEJEM – the newest in Europe scientific journal on energetic materials It provides a forum for scientists interested in the exchange of practical and theoretical knowledge concerning energetic materials: propellants, explosives and pyrotechnics. The journal focuses in particular on the latest results of research on various problems of energetic materials. Topics: ignition, combustion and detonation phenomenon; formulation, synthesis and processing; analysis and thermal decomposition; toxicological, environmental and safety aspects of energetic materials production, application, utilization and demilitarization; molecular orbital calculations; detonation properties and ballistics; biotechnology and hazards testing CEJEM presents original research and interesting reviews. Contributions are from experts in chemistry, physics and engineering from leading research centers in Europe, America and Asia. All submissions are independently refereed by Editorial Board members and by external referees chosen on international basis.