邓宽海,程金亮,林元华,黄耕,刘冰,梅宗斌,秦大伟.基于气-固两相流喷嘴实验的20G钢冲蚀机理研究[J].表面技术,2024,53(17):50-61.
DENG Kuanhai,CHENG Jinliang,LIN Yuanhua,HUANG Geng,LIU Bing,MEI Zongbin,QIN Dawei.Erosion Mechanism of 20G Steel Based on Gas-solid Two-phase Flow Nozzle Experiment[J].Surface Technology,2024,53(17):50-61 |
| 基于气-固两相流喷嘴实验的20G钢冲蚀机理研究 |
| Erosion Mechanism of 20G Steel Based on Gas-solid Two-phase Flow Nozzle Experiment |
| 投稿时间:2023-09-25 修订日期:2024-03-14 |
| DOI:10.16490/j.cnki.issn.1001-3660.2024.17.004 |
| 中文关键词: 冲蚀磨损 20G钢 冲蚀机理 气固两相流 冲蚀速率方程 冲蚀试验 |
| 英文关键词:erosion wear 20G steel erosion mechanism gas-solid flow erosion rate equation erosion experiment |
| 基金项目:国家自然科学基金(52074232,52474011);四川省自然科学基金重点项目(2022NSFSC0028);四川省青年科学基金(2022NSFSC0994);广东省自然科学基金(2022A1515010512);广东省教育厅青年创新人才项目(2020KQNCX047) |
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| Author | Institution |
| DENG Kuanhai | State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation, Southwest Petroleum University, Chengdu 610500, China |
| CHENG Jinliang | State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation, Southwest Petroleum University, Chengdu 610500, China |
| LIN Yuanhua | State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation, Southwest Petroleum University, Chengdu 610500, China |
| HUANG Geng | State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation, Southwest Petroleum University, Chengdu 610500, China |
| LIU Bing | Guizhou Aerospace Tianma Electromechanical Technology Co., Ltd., Guizhou Zunyi 563000, China |
| MEI Zongbin | Sichuan Huayu Drilling Equipment Co., Ltd., Sichuan Luzhou 646000, China |
| QIN Dawei | Guangdong Institute of Petrochemical Engineering, Guangdong Maoming 525000, China |
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| 中文摘要: |
| 目的 由天然气管道内壁减薄及穿孔导致的天然气泄漏事故频繁发生,输气管道面临着日益严重的冲蚀磨损问题。针对这一问题需要明确输气管道材料的冲蚀行为及机理,为抗冲蚀材料设计和延长管道使用寿命等工作的开展提供有效支撑。方法 基于ASTM-G76测试标准,采取气-固喷嘴冲蚀试验研究方法,利用空气射流冲蚀实验机,开展不同冲击角度和冲击速度下天然气管道材料20G钢的气-固冲蚀实验;采用扫描电子显微镜、激光粒度分析仪等设备分析试样表面冲蚀形貌及特征;采用Ahlert冲蚀模型对实验数据进行拟合,建立20G钢的冲蚀率方程。结果 当冲击速度(15~72 m/s)增大时,冲蚀率随之增大。当冲击角度(15°~90°)增加时,冲蚀率随之减小。冲蚀面积随着冲击角度的增加而减小。在低冲击角度下(15°、30°),固相颗粒的“犁削”为主要冲蚀及材料移除机制。在中等冲击角度下(45°、60°),冲蚀机制呈现混合形式,犁削、压实与开裂共同作用于材料表面。在高冲击角度下(75°、90°),以压实和开裂为主要冲蚀及材料移除机制。结论 在气固两相流作用下,20G钢的冲蚀磨损过程符合典型的塑性材料冲蚀规律。颗粒冲击速度不会直接影响冲蚀机制,颗粒冲击能量的变化是影响冲蚀率的主要因素。建立了适用于天然气管道材料抗冲蚀性能对比和CFD冲蚀模型的冲蚀速率方程。 |
| 英文摘要: |
| In recent years, natural gas leakage accidents occur frequently due to the thinning and perforation of the inner wall of natural gas pipelines, and the natural gas pipelines are faced with increasingly serious erosion and wear problems. To solve this problem, the work aims to clarify the erosion behavior and mechanism of gas pipeline materials to provide effective support for the design of anti-erosion materials and the extension of pipeline service life. Based on the ASTM-G76 test standard, the gas-solid two-phase flow nozzle erosion test research method was adopted and the air jet erosion test equipment was used to carry out erosion experiments on 20G steel, a commonly used material for natural gas pipelines, at different impact angles and impact speed. The micromorphologies of the samples were analyzed by means of specialized microinstruments. Ahlert erosion model was used to fit the experimental data, and the erosion rate equation of 20G steel was established. The sample size of 20G steel was processed into 20 mm×20 mm×5 mm (impact angle 15° and 30°) and 25 mm×25 mm× 5 mm (impact angle 45°-90°) with laser cutting instrument, and the surface of the pattern was polished with sandpaper to be eroded, cleaned, dehydrated and blown dry, and then placed in the dryer for use, and finally weighed with a balance. Before the experiment, the abrasive was weighed and dried in a 150° drying oven for 2 hours, and then the abrasive was poured into the sand storage tank in the equipment. With the help of air jet erosion device, the abrasive was sucked into the nozzle, and accelerated in the air flow, to realize impact pattern. During the experiment, the impact angle was adjusted by replacing the sample brackets with different angles (15°, 30°, 45°, 60°, 75° and 90°) to achieve the required conditions of the experiment. After the experiment, the debris on the surface of the pattern was cleaned, dehydrated and dried, and the weight of the pattern after erosion was weighed and the weight loss was calculated. The erosion mechanism was studied by scanning electron microscope (SEM). When the particle impact angle (15°-90°) increased, the erosion rate decreased. However, when the particle impact speed (15-72 m/s) increased, the erosion rate increased. When the impact angle increased, the erosion area decreased. At low impact angles (15° and 30°), the "plowing" of solid particles was the main erosion and material removal mechanism. At moderate impact angles (45° and 60°), the erosion mechanism presented a mixed form, with ploughing, compaction and cracking acting together on the material surface. At high impact angles (75° and 90°), compaction and cracking were the main erosion and material removal mechanisms. It is concluded that the erosion wear process of 20G under the action of gas-solid two-phase flow conforms to the typical erosion law of plastic materials, and the removal mechanism is not directly affected by particle impact speed, and the change of particle impact energy is the main factor affecting the erosion rate. The erosion rate equation which is suitable for comparison of erosion resistance of natural gas pipeline materials and CFD erosion model is established. The theory of erosion wear is improved, which provides effective theoretical support for solving practical erosion problems in future engineering. |
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