首页|期刊导航|爆炸与冲击|基于统一强度理论的弹体侵彻天然气管道局部损伤塑性半径统一解

基于统一强度理论的弹体侵彻天然气管道局部损伤塑性半径统一解OA

Unified solution for plastic radius of local damage in gas pipeline under projectile penetration based on the unified strength theory

中文摘要英文摘要

为揭示弹体高速侵彻下天然气管道的局部损伤机理,基于侵彻试验、数值模拟与理论推导,建立了一种基于统一强度理论的管道损伤塑性半径统一解.通过开展L415M管道钢的弹体侵彻试验,获取了管道着弹面撞击形态、塑性区范围及塑性半径等关键参数.基于试验结果和ANSYS/Workbench建立动力学模型,对管道的局部应力场和应变分布进行了数值模拟,并引入统一强度理论对中间主应力参数b的敏感性进行了系统分析,进而结合有限柱形空腔膨胀模型,推导建立了管道损伤塑性半径的解析表达式,并提出了弹体侵彻天然气管道局部损伤失效准则,当侵彻荷载下测量得到的塑性半径超过由材料单向拉伸断裂应变εf与模型参数A(含中间主应力参数b)所限定的临界值rmax时,可判定管道发生局部损伤失效.结果表明:当b=0.2 时,理论预测与试验结果吻合最佳,相对误差小于 10%,能较准确描述管道局部塑性变形及损伤规律.本研究为长输天然气管道在高速冲击载荷下的安全评估与防护设计提供理论依据和工程参考.

To reveal the local damage mechanism of natural gas pipelines subjected to high-velocity projectile penetration,a unified solution for the plastic radius of pipeline damage was established based on the unified strength theory,integrating penetration tests,numerical simulations,and theoretical analysis.Through projectile penetration tests on L415M pipeline steel,key parameters including impact feature on the impacted surface of the pipeline,plastic zone and plastic radius were obtained.Based on the experimental results and ANSYS/Workbench,a dynamic model was developed to numerically simulate the distribution of local stress fields and strains in the pipeline.Sensitivity analysis of the intermediate principal stress parameter b was conducted using unified strength theory.Furthermore,in conjunction with a finite cylindrical cavity expansion model,an analytical expression for the plastic radius of pipeline damage was derived,and a failure criterion for local damage of natural gas pipelines under projectile penetration was proposed.According to the criterion,when the plastic radius measured under penetration loading exceeds the critical value rmax defined by the uniaxial tensile fracture strain εf of the material and the model parameter A(which incorporates the intermediate principal stress parameter b),local damage failure of the pipeline can be determined.The results indicate that the theoretical predictions are in best agreement with experimental data whenb=0.2,with a relative error of less than 10%.This approach accurately describes the local plastic deformation and damage behavior of the pipeline,providing a theoretical basis and engineering reference for the safety assessment and protection design of long-distance natural gas pipelines under high-velocity impact loading.

崔莹;申瑞;赵均海;屈展

西安石油大学管道工程学院,陕西 西安 710065||西安石油大学陕西省油气井及储层渗流与岩石力学重点实验室,陕西 西安 710065西安石油大学管道工程学院,陕西 西安 710065||西安石油大学陕西省油气井及储层渗流与岩石力学重点实验室,陕西 西安 710065长安大学建筑工程学院,陕西 西安 710061西安石油大学管道工程学院,陕西 西安 710065||西安石油大学陕西省油气井及储层渗流与岩石力学重点实验室,陕西 西安 710065

数理科学

统一强度理论有限柱形空腔膨胀理论侵彻荷载天然气管道损伤统一解

unified strength theoryfinite cylindrical cavity expansion theorypenetration loadnatural gas pipelineunified damage solution

《爆炸与冲击》 2026 (6)

98-112,15

陕西省自然科学基础研究计划(2023-JC-YB-296)陕西省教育厅重点科学研究计划(22JT035)四川省重点实验室开放基金(24kfck02)

10.11883/bzycj-2025-0379

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