基于CFD-DPM-MD模拟压裂管汇缓冲弯头的冲蚀磨损行为及作用机理

doi:10.3901/JME.260022

摘要/Abstract

摘要： 油气开采水力压裂作业中，含砂压裂液在缓冲弯头弯肘处的高速湍流引发严重管壁冲蚀磨损，其复杂机制使得抗冲蚀优化面临挑战。为揭示冲蚀机理，构建了耦合流体力学、离散元与分子动力学的多尺度预测模型(CFD-DPM-MD)。研究发现：缓冲弯头主要冲蚀区域位于相贯线处，其损伤与颗粒滞留无关，而由涡旋诱导的颗粒多角度碰撞主导。微观冲击分析表明，固相颗粒碰撞导致壁面原子应力与动能超限时引发位错爆炸，产生非相变塑性变形及剥落。研究还发现，尽管40°冲蚀角下剪切应变面积最大，但65°冲蚀角形成的特殊形貌导致颗粒-壁面接触面积更大，最终冲蚀程度更严重。因此，提升缓冲弯头使用寿命的有效途径包括应用高抗剪切冲蚀涂层或设计特殊形貌壁面以减轻高冲蚀角度损伤。

关键词: 液固两相, 流体力学仿真, 分子动力学仿真, 冲蚀磨损

Abstract: In hydraulic fracturing operations for oil and gas extraction, high-speed turbulent flow of sand-laden fracturing fluid in buffer elbows causes severe erosion wear on the pipe wall. The complex mechanisms involved pose significant challenges for optimizing erosion resistance. To elucidate the erosion mechanism, a multi-scale prediction model (CFD-DPM-MD) coupling fluid dynamics, discrete element modeling, and molecular dynamics is developed. Key findings indicate that the primary erosion zone in the buffer elbow occurs at the intersection line. This damage is not related to particle retention but is dominantly driven by multi-angle particle collisions induced by vortices. Microscopic impact analysis reveals that collisions between solid particles and the wall surface trigger dislocation explosions when atomic stresses and kinetic energy exceed critical thresholds, leading to non-phase-transition plastic deformation and material spalling. Furthermore, while a 40° impact angle generates the largest shear strain area, a 65° impact angle creates a specific erosion morphology that increases the particle-wall contact area, ultimately resulting in more severe erosion. Consequently, effective strategies to enhance buffer elbow service life include applying high-shear-resistance erosion-resistant coatings or designing wall surfaces with specific morphologies to mitigate damage from high-impact angles.

Key words: solid-liquid two-phase, fluid dynamics simulation, molecular dynamics simulation, erosion wear

中图分类号:

TG156

刘云海, 郑杜塬, 祝效华. 基于CFD-DPM-MD模拟压裂管汇缓冲弯头的冲蚀磨损行为及作用机理[J]. 机械工程学报, 2026, 62(1): 296-309.

LIU Yunhai, ZHENG Duyuan, ZHU Xiaohua. Simulation of Erosion Behavior and Mechanism of Buffer Elbow in Fracturing Manifold Based on CFD-DPM-MD[J]. Journal of Mechanical Engineering, 2026, 62(1): 296-309.

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