程书铭,曹宇鹏,陆华,花国然,王振刚,陈真,丁海华.超高压水射流冲蚀船用A级钢表面实验研究[J].表面技术,2022,51(6):229-238.
CHENG Shu-ming,CAO Yu-peng,LU Hua,HUA Guo-ran,WANG Zhen-gang,CHEN Zhen,DING Hai-hua.Experimental Study on Surface Erosion of Grade-A Marine Steel by Ultra-high Pressure Water Jet[J].Surface Technology,2022,51(6):229-238 |
| 超高压水射流冲蚀船用A级钢表面实验研究 |
| Experimental Study on Surface Erosion of Grade-A Marine Steel by Ultra-high Pressure Water Jet |
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| DOI:10.16490/j.cnki.issn.1001-3660.2022.06.020 |
| 中文关键词: 超高压水射流 船用A级钢 冲蚀 表面形貌 微观组织 动态应变 |
| 英文关键词:ultra-high pressure water jet Grade-A marine steel erosion surface morphology microscopic tissue dynamic strain |
| 基金项目:国家工业和信息化部高技术船舶科研专项(MC–202031–Z07);国家自然科学基金(51979138,52109106);国家重点研发计划(2019YFB2005300);江苏省博士后基金(2021K606C);江苏省高校自然科学研究面上项目(21KJB460018);南通市科技计划(JC2020149) |
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| Author | Institution |
| CHENG Shu-ming | College of Mechanical Engineering, Nantong University, Jiangsu Nantong 226019, China |
| CAO Yu-peng | College of Mechanical Engineering, Nantong University, Jiangsu Nantong 226019, China;3D Printing Technology Research Institute, Nantong Institute of Technology, Jiangsu Nantong 226001, China;Nantong COSCO Shipyard Co., Ltd., Jiangsu Nantong 226006, China |
| LU Hua | Nantong COSCO Shipyard Co., Ltd., Jiangsu Nantong 226006, China |
| HUA Guo-ran | College of Mechanical Engineering, Nantong University, Jiangsu Nantong 226019, China |
| WANG Zhen-gang | Nantong COSCO Shipyard Co., Ltd., Jiangsu Nantong 226006, China |
| CHEN Zhen | Nantong COSCO Shipyard Co., Ltd., Jiangsu Nantong 226006, China |
| DING Hai-hua | Nantong COSCO Shipyard Co., Ltd., Jiangsu Nantong 226006, China |
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| 中文摘要: |
| 目的 研究超高压水射流与船用A级钢表面的相互作用及冲蚀机理。方法 使用200 MPa的超高压水对船用A级钢进行射流冲蚀实验,并用20 MPa高压水射流进行对比实验。利用ASMC2–4电阻应变仪采集水射流冲击过程中船板背面的动态应变信号,同时使用扫描电子显微镜、透射电子显微镜、X射线衍射仪等设备对船用A级钢冲击前的微观组织、物相和冲击后的材料表面形貌与元素分布进行观察分析。结果 在200 MPa压力下船用A级钢冲击中心区域背面平均微应变为180×10−6,微应变振幅为35×10−6~50×10−6,水射流对A级钢的冲击力为循环脉动交变应力;在射流交变应力作用下材料表面发生疲劳破坏,水射流冲蚀后A级钢中心区域以长条状渗碳体硬质相为主,还存在有未被冲蚀的珠光体组织;在200 MPa超高压射流作用下材料表面还存在着典型的剥落坑、层蚀、穴蚀等断裂形貌。结论 建立了船用A级钢水射流冲蚀剥离模型,阐明了水射流冲蚀作用机理。 |
| 英文摘要: |
| With advantages such as zero pollution, high degree of automation and high efficiency, ultra-high pressure water jet rust removal technology is well in line with China’s advocacy for green and automated manufacturing and has stood out in the new wave of green vessel repair technologies, making it one of the most intensively studied topics. Grade-A marine steel, as an important material for marine quality steel plates, is highly resistant to corrosion and fatigue and accounts for one fifth of the total vessel building cost. Therefore, researching the interaction between water jet and marine quality steel plate, as well as the matrix damage process after rust removal, is of great significance for green vessel repairing. In order to study the interaction between ultra-high pressure water jet and the surface of Grade-A marine steel and the erosion mechanism of the former on the latter, a jet erosion test on Grade-A marine steel was carried out with 200 MPa ultra-high pressure water, and a comparative experiment was also conducted with 20 MPa water jet. The changes of microstructure, phase and surface morphology of Grade-A marine steel were analyzed under different pressures. The specific experimental process and parameters were as follows:Five groups of samples with specifications of 50 mm×50 mm×10 mm were made respectively for the 200 MPa and 20 MPa erosion tests. Using the jet medium of clean water, the experiment was conducted at room temperature with a jet impact distance of 30 mm and an impact angle of 90°. At times of water jet impacts, ASMC2-4 resistance strain gauge was used to collect the dynamic strain signal on the back of the vessel plate. Scanning electron microscope, transmission electron microscope and X-ray diffractometer were applied to observe and analyze the microstructure, phase and surface morphology and element distribution of Grade-A marine steel before impact. Under the pressure of 200 MPa, the average micro strain on the back of the impact center area of Grade-A marine steel was 180×10−6, micro strain amplitude was 35×10−6-50×10−6, and the impact force of water jet on Grade-A marine steel was cyclic pulsating alternating stress; The impact force of water jet at 20 MPa decreased radially from the center, while the pressure at the center and edge of the jet at 200 MPa was basically unchanged, and the difference in pressure could be ignored. Under the action of jet alternating stress, fatigue failure occurred to the material surface. After water jet erosion, the central area of Grade-A marine steel was dominated by long strip cementite hard phase, and there was also pearlite structure that had not been eroded; Under the action of 200 MPa ultra-high pressure jet, there were also typical fracture morphologies such as spalling pit, layer corrosion and cavitation corrosion on the material surface. Looking at the gradual peeling process of different hardness structures under the action of water jet cyclic alternating stress and water wedge, this paper establishes an erosion stripping model of Grade-A marine steel to discuss the erosion mechanism of water jet. |
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