郭磊,王家庆,明子航,郭万金,马臻,靳淇超.基于弹性基体磨具的3D打印高温合金叶片磨抛试验[J].表面技术,2023,52(2):43-54.
GUO Lei,WANG Jia-qing,MING Zi-hang,GUO Wan-jin,MA Zhen,JIN Qi-chao.Grinding and Polishing Test of 3D-printed Superalloy Blade Based on Elastic-matrix Abrasive Tool[J].Surface Technology,2023,52(2):43-54 |
| 基于弹性基体磨具的3D打印高温合金叶片磨抛试验 |
| Grinding and Polishing Test of 3D-printed Superalloy Blade Based on Elastic-matrix Abrasive Tool |
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| DOI:10.16490/j.cnki.issn.1001-3660.2023.02.005 |
| 中文关键词: 自适应磨削 柔性抛光 镍基高温合金 轨迹规划 表面质量 |
| 英文关键词:adaptive grinding and polishing compliant polishing nickel-based superalloy trajectory planning surface quality |
| 基金项目:国家自然科学基金(51805044);陕西省自然科学基础研究计划(2022JM–254);中国博士后科学基金(2020M673318);机械传动国家重点实验室开放基金(SKLMT–MSKFKT–202006) |
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| Author | Institution |
| GUO Lei | School of Construction Machinery, Chang'an University, Xi'an 710064, China;State Key Laboratory of Mechanical Transmissions, Chongqing University, Chongqing 400044, China |
| WANG Jia-qing | School of Construction Machinery, Chang'an University, Xi'an 710064, China |
| MING Zi-hang | School of Construction Machinery, Chang'an University, Xi'an 710064, China |
| GUO Wan-jin | School of Construction Machinery, Chang'an University, Xi'an 710064, China |
| MA Zhen | Xi'an Institute of Optics and Precision Mechanics of CAS, Xi'an 710119, China |
| JIN Qi-chao | School of Construction Machinery, Chang'an University, Xi'an 710064, China |
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| 中文摘要: |
| 目的 验证弹性基体磨具自适应磨削抛光加工增材制造镍基高温合金叶片的工艺可行性。方法 以硅橡胶基体磨具弹性磨抛技术为基础,建立弹性磨具与叶片接触的有限元模型,分析磨具与工件接触区域内应力和材料去除分布。以有限元分析结果为指导,研究磨具接触变形和材料去除对轨迹规划的影响,确定合理的轨迹步长和间距,并通过控制工件位姿角的变化,保证在磨抛过程中磨具与工件的接触状态不变。以GH4169镍基合金叶片为加工对象,采用硅橡胶弹性固结磨料磨具在小型四轴加工平台上进行磨抛试验。结果 仿真结果表明,弹性磨具与曲面工件之间的接触区域为椭圆形,应力和材料去除分布都由椭圆心到周围逐渐减小;当弹性磨具的压缩量为3 mm时,基于弹性接触有限元分析结果确定的最优轨迹间距为9 mm。试验结果表明,采用自适应磨抛轨迹抛光后,叶片表面无明显划痕和抛光纹理,表面粗糙度Ra由开始的1.846 μm降至0.182 μm,标准差由0.108 μm降至0.026 μm,材料去除率为3.432×109 μm3/min。结论 硅橡胶弹性固结磨料磨具可用于GH4169镍基合金叶片的超精密磨抛,基于弹性磨具接触区域应力分布及工件位姿变换提出的自适应轨迹规划能够保证叶片磨抛区域表面质量的一致性。 |
| 英文摘要: |
| Shape-Adaptive Polishing (SAP) is an effective method for the polishing of hard and brittle materials. The work aims to verify the feasibility of the adaptive grinding and polishing of 3D-printed nickel-based superalloy engine blades with elastic matrix abrasive tools. Firstly, a finite element model of the elastic contact between the polishing tool and the blade was established based on the elastic grinding and polishing techniques with silicon rubber-based abrasive tools. In addition, the stress distribution and material removal function within the contact area were analyzed. Furthermore, the effect of contact deformation and material removal of abrasive tools on trajectory planning was studied according to the finite element analysis. Finally, the reasonable trajectory step size and spacing were determined, where the contact state between the grinding tool and the workpiece was kept unchanged during the grinding and polishing process. The experimental tests were carried out on a desktop CNC machining system. EOSM290 3D printer was employed to fabricate the blade, and the GH4169 nickel-based alloy was selected as the source material. The preparation of the abrasive tool was realized by a molding process, where the Smooth-On Ecoflex 0050 silicon rubber and micron-sized diamond grains were selected as the binder matrix material and abrasives. During the experiment, the rotation axis of the silicon rubber-based abrasive tool was consistently vertical to the blade surface by controlling the position and orientation of the blade. The simulation results showed the elliptical contact area between the elastic tool and the curved surface workpiece. Also, the stress distribution and material removal rate decreased gradually from the ellipse's center to the periphery. The optimal track spacing determined was 9 mm when the compression of the elastic abrasive tool was 3 mm. The optimal track spacing increased with the increasing compression of the elastic abrasive tool. The polished blade surface topography was observed through the optical microscope. The experimental results showed that the blade surface had no noticeable scratches and dents after polished with the adaptive polishing tool and planned trajectory. The reason was that the elastic matrix abrasive tool had excellent flexibility in the polishing process and deformed with the blade surface according to the shape, thereby achieving flexible adaptive and uniform polishing under the condition of ensuring the stability of polishing parameters. A group of 10 sample points was taken in the polishing area of the blade surface for measuring the surface roughness by Mitutoyo SURFTEST SJ-310 roughness meter. The surface roughness value was reduced from 1.846 μm to 0.182 μm, and the standard deviation was decreased from 0.108 μm to 0.026 μm. The blade weight loss before and after polishing was measured by an electronic balance, and the material removal rate was calculated as 3.432×109 μm3/min. In summary, the silicon rubber-based abrasive tool can realize the precision polishing of GH4169 nickel-based alloy blades. The adaptive trajectory planning based on the stress distribution in the contact area of the elastic abrasive tool and the transformation of the workpiece position and orientation is promising to improve the consistency of the surface quality in the blade polishing area. |
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