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非药式水下爆炸冲击波加载的PD-SPH建模与分析OA

Modeling and analysis of non-explosive underwater shock loading using a PD-SPH coupling method

中文摘要英文摘要

针对舰艇抗爆炸冲击性能评估面临的强非线性流固耦合、结构大变形及损伤破坏演化等关键力学问题,耦合近场动力学(peridynamics,PD)和光滑粒子流体动力学(smoothed particle hydrodynamics,SPH)各自的优势,提出了适用于水下爆炸冲击模拟的高效PD-SPH数值方法.采用SPH模拟水下冲击波传播及其流固耦合效应,采用PD方法精确表征固体结构从弹性变形至渐进损伤破坏的全过程力学行为,建立了非药式水下爆炸冲击波加载装置的PD-SPH数值模型.针对大规模粒子计算效率瓶颈,开发了基于区域分解和数据通信机制的多GPU(graphics processing unit)并行计算框架.系统验证和并行效率测试表明,该方法可准确预测冲击波壁面压力和靶体动态变形,成功复现薄板结构的典型裂纹扩展模式,并可用于开展复杂夹层板毁伤全过程模拟.在超过 500 万个粒子的复杂流固耦合场景中,8 卡RTX4090 相比单卡RTX4090 加速比为 4.13,并行效率为 51.6%,实际计算时间可以压缩到近 1 h.同时,多GPU并行与传统CPU(central processing unit)并行相比,加速比可达 9 倍以上.

The evaluation method of ship's explosion shock resistance is challenged by some key mechanical problems,such as strong nonlinear fluid-structure coupling,large-deformation and failure evolution of solid structure.By coupling the respective advantages of peridynamics(PD)and smoothed particle hydrodynamics(SPH),an efficient PD-SPH numerical method suitable for underwater explosion shock simulations was developed.The SPH method was employed to simulate underwater shock wave propagation and fluid-structure interaction,while the PD method accurately characterized the complete mechanical behavior of solid structures from elastic deformation to progressive damage failure.A PD-SPH numerical model was established for non-explosive underwater shock loading devices.In the non-ordinary state-based peridynamics(NOSB-PD)framework,the Johnson-Cook damage model was introduced.To suppress the occurrence of numerical instability,the artificial stiffness form was introduced by increasing the internal constraints between particles.To improve the computational efficiency in large-scale simulations,a multi-GPU(graphics processing unit)parallel computing framework based on domain decomposition and data-communication mechanisms was established.The domain decomposition was carried out through the Eulerian format.When particles move from one domain to another,the physical quantities of the particles were exchanged for information.Model validation and parallel efficiency tests demonstrate that the proposed method can accurately predict shock wave wall pressure and target dynamic deformation,successfully reproduce typical crack propagation patterns in thin-plate structures and simulate the entire damage process of complex grid sandwich structure.In complex fluid-structure coupling scenarios with more than 5 million particles,the 8*RTX4090 achieved an acceleration ratio of 4.13 compared to a single RTX4090,with a parallel efficiency of 51.6%.The actual computation time can be reduced to nearly 1 hour.Meanwhile,compared with traditional CPU(central processing unit)parallelism,the multi-GPU parallelism can achieve an acceleration ratio of more than 9 times.The research outcomes provide a high-precision and efficient numerical analysis tool for the design of explosion-resistant naval structures,offering significant reference value for engineering applications of fluid-structure interaction in underwater explosion problems.

陈丁;余泽洋;姚学昊;周章涛;王孟元;黄丹

福州大学紫金地质与矿业学院,福建 福州 350108河海大学力学与工程科学学院,江苏 南京 211100河海大学力学与工程科学学院,江苏 南京 211100河海大学力学与工程科学学院,江苏 南京 211100中国船舶科学研究中心,江苏 无锡 214082中国船舶科学研究中心,江苏 无锡 214082

数理科学

光滑粒子流体动力学近场动力学水下爆炸流固耦合冲击波

smoothed particle hydrodynamicsperidynamicsunderwater explosionfluid-structure interactionshock wave

《爆炸与冲击》 2026 (1)

98-111,14

国家自然科学基金(12302257,12072104)船舶结构安全全国重点实验室开放基金(Naklas2024KF006-K)

10.11883/bzycj-2025-0180

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