Numerical Analysis on the Blast Field From Gas Pipeline Burst Considering Fluid-Structure Interaction

Yi Ren, Yang Du, F. Zhou
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Abstract

The blast wave propagates into the surrounding air when the high-pressure gas pipeline burst. Both temperature and pressure increase very rapidly. The generation of the blast wave and structural dynamic fracture are tightly coupled together during the burst of the high-pressure gas pipeline. However, fracture behavior and characteristics that influence blast waves’ intensity and spatial shape are rarely studied. This paper establishes a numerical model incorporating strain-based failure criteria for pipe material and fluid-structure coupling algorithm. The dynamic crack growth of the pipe and the outer blast wave propagation can be successfully captured in every timestep. The model is validated by comparing the simulated explosion pressure history and peak overpressure outside the pipeline with the experimental results. The blast wave intensity changes and the distribution of overpressure in the jet direction are clarified. Then some critical parameters of the resulting fracture and blast wave are examined, such as the pipe diameter and wall thickness. Specifically, the relationship between pipe fracture and the generated blast field is discussed, providing a deeper understanding of this highly transient and strong fluid-structure interaction problem. The results would benefit the prediction and accident investigation of high-pressure gas pipeline rupture.
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考虑流固耦合的天然气管道爆破爆炸场数值分析
高压输气管道爆破时,冲击波向周围空气传播。温度和压强都迅速上升。高压输气管道爆破过程中爆炸波的产生与结构动力断裂是紧密耦合在一起的。然而,对影响冲击波强度和空间形态的断裂行为和特征的研究却很少。本文建立了结合管材应变失效准则和流固耦合算法的数值模型。在每个时间步长都能成功地捕捉到管道的动态裂纹扩展和外爆波传播。通过将模拟爆炸压力历史和管道外峰值超压与实验结果进行对比,验证了模型的正确性。阐明了冲击波强度的变化和射流方向上超压的分布。然后对爆破产生的裂缝和冲击波的一些关键参数进行了检测,如管径和壁厚。具体而言,讨论了管道断裂与产生的爆炸场之间的关系,从而对这一高度瞬态和强流固耦合问题有了更深入的了解。研究结果对高压输气管道破裂的预测和事故调查具有一定的指导意义。
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