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钽合金EFP靶后破片的空间散布特性OA

Spatial dispersion characteristics of behind-armor debris generated during the penetration of tantalum alloy explosively-formed projectile

中文摘要英文摘要

为研究钽合金爆炸成型弹丸(explosively-formed projectile,EFP)侵彻靶板产生靶后破片的空间散布,首先开展了钽合金 EFP 侵彻 45 钢的 X 光及破片散布试验;其次,采用经试验验证的 FE-SPH(finite element-smoothed particle hydrodynamics)固定耦合方法开展了多种弹、靶条件下 EFP 垂直侵彻靶板的数值模拟,获得了靶后破片空间散布的数据集;最后,采用基于贝叶斯优化的支持向量回归对靶后破片密集飞散角数据进行训练,得到了基于贝叶斯优化的支持向量回归模型.研究结果表明:从试验结果来看,靶后破片云形貌为典型的截椭球状,由于钽、钢密度差异导致不同材料破片径向膨胀能力不同,钢破片分布在椭球的外表面而钽破片分布在椭球的内表面,靶后破片主要集中在验证靶上中心穿孔处周围的圆形区域;采用 FE-SPH 固定耦合方法模拟再现了靶后破片的形成过程,得到的靶后破片云形貌与试验结果十分接近,靶后破片平均最大飞散角与试验结果的相对误差不超过 10%,验证了数值模拟结果的准确性;建立的基于贝叶斯优化的支持向量回归模型能够实现对不同靶板厚度、着靶速度条件下靶后破片的密集飞散角的准确预测,数值模拟结果与模型预测结果的最大相对误差均小于 10%,在此基础上可以实现对靶后一定距离内验证靶毁伤面积的快速预测.

To investigate the spatial dispersion characteristics of behind-armor debris(BAD)generated by the penetration of tantalum alloy explosively-formed projectile(EFP)into steel targets,a comprehensive study combining experimental testing,numerical simulation,and machine learning prediction was performed.First,X-ray imaging and fragment-distribution experiments were conducted on 45 steel targets penetrated by tantalum alloy EFP to obtain initial experimental data.Subsequently,the finite element-smoothed particle hydrodynamics(FE-SPH)fixed-coupling method,which had been validated by the experimental data,was employed to simulate the perforation process.These numerical simulations were carried out under a wide range of working conditions,specifically varying the projectile velocity and target thickness.Through this process,a comprehensive dataset describing the spatial dispersion of BAD was generated.Finally,to achieve rapid prediction capabilities,a support vector regression(SVR)model was established.The Bayesian optimization algorithm was utilized to train the model using the dense-fragment dispersion angle data extracted from the simulation dataset,thereby creating a robust predictive model for spatial dispersion of BAD.The experimental results indicate that the morphology of the BAD cloud exhibits a typical truncated-ellipsoidal shape.Due to the density difference between tantalum and steel,fragments composed of different materials display distinct radial expansion behaviors,i.e.steel fragments are distributed along the outer surface of the ellipsoid whereas tantalum fragments are concentrated on the inner surface.Spatially,the debris is primarily concentrated within a circular region surrounding the central perforation area of the witness plate.The FE-SPH fixed-coupling method successfully reproduced the BAD formation process,yielding debris-cloud morphologies that closely match the experimental results.The relative error between the simulated and measured mean maximum fragment dispersion angles is less than 10%,thereby confirming the accuracy of the numerical simulations.Furthermore,the analysis reveals that the Bayesian-optimized SVR model enables accurate prediction of dense-fragment dispersion angles under varying target thicknesses and EFP impact velocities,with maximum relative errors below 10%.Based on these predictions,the damage area on witness plates within a certain distance behind the target can be rapidly estimated.

位国旭;徐宏伟;郭锐;李向东;张磊;姬龙

南京理工大学机械工程学院,江苏 南京 210094西安现代控制技术研究所陆空基信息感知与控制全国重点实验室,陕西 西安 710065南京理工大学机械工程学院,江苏 南京 210094南京理工大学机械工程学院,江苏 南京 210094西安现代控制技术研究所陆空基信息感知与控制全国重点实验室,陕西 西安 710065西安现代控制技术研究所陆空基信息感知与控制全国重点实验室,陕西 西安 710065

数理科学

EFP靶后破片空间散布支持向量回归贝叶斯优化

explosively formed projectilebehind-armor debrisspatial dispersionsupport vector regressionBayesian optimization

《爆炸与冲击》 2026 (5)

118-133,16

中央高校基本科研业务费专项资金(30925020102)

10.11883/bzycj-2025-0326

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