非晶合金激光制造技术研究进展

姚燕生; 唐建平; 张亚超; 胡衍雷; 吴东

doi:doi:10.3788/CJL202148.0202012

中国激光, 2021, 48 (2): 0202012, 网络出版: 2021-01-06

非晶合金激光制造技术研究进展下载： 1827次特邀综述

Development of Laser Fabrication Technology for Amorphous Alloys

姚燕生 ^1,3,*唐建平 ^1,2张亚超 ^2,*胡衍雷 ²吴东 ²

作者单位

¹ 安徽建筑大学机械与电气工程学院, 安徽合肥 230601

² 中国科学技术大学工程科学学院, 安徽合肥 230027

³ 安徽省工程机械智能制造重点实验室, 安徽合肥 230601

图 & 表

图 1. 不同体系的厘米级块体非晶合金锭^[6]。(a) Pd-Cu-Ni-P; (b) Zr-Al-Ni-Cu; (c) Cu-Zr-Al-Ag;(d) Ni-Pd-P-B

Fig. 1. Centimeter-sized bulk amorphous alloy ingots of different systems^[6]. (a) Pd-Cu-Ni-P; (b) Zr-Al-Ni-Cu; (c) Cu-Zr-Al-Ag; (d) Ni-Pd-P-B

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图 2. 选区激光熔化成形非晶构件及其非晶态结构的表征^[14]。(a)成形的非晶构件;(b) 快淬薄带、粉末以及成形构件的XRD图

Fig. 2. Amorphous alloy components formed by selective laser melting and the characterization of amorphous structure^[14]. (a) Amorphous alloy components formed by selective laser melting; (b) XRD patterns of as-spun ribbon, powders, and formed components

下载图片查看原文

图 3. Ti6Al4V合金与增材制造锆基块体非晶合金的磨损行为、生物相容性的比较^[25]。(a)摩擦因数;(b)磨损率; (c)动电位极化曲线; (d)体外细胞培养情况

Fig. 3. Comparison of wear behavior and biocompatibility between Ti6Al4V alloy and 3D printed Zr-based bulk amorphous alloy^[25]. (a) Friction coefficient; (b) wear rate; (c) potentiodynamic polarization curves; (d) in vitro cell culture

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图 4. 焊接锆基非晶合金在不同扫描速度下的宏观二维图与结构特征^[30]。(a)(b) 2m·min^-1; (c) 4m·min^-1; (d) 8m·min^-1; (e) 各数字对应区域的XRD图

Fig. 4. Macroscopic planar views and structural characteristics of welded Zr-based amorphous alloy at different scanning speeds^[30].(a)(b) 2m·min^-1; (c) 4m·min^-1; (d) 8m·min^-1; (e) XRD patterns of the corresponding regions

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图 5. Zr₆₅Al_7.5Ni₁₀Cu_17.5多层非晶合金涂层第7层、第4层和第1层的结构特征与耐腐蚀性能测试结果^[53]。(a) XRD图;(b)动电位极化曲线

Fig. 5. Structural characteristics and corrosion resistance test results of the seventh layer, fourth layer, and first layer of multi-layer amorphoous alloy coating Zr₆₅Al_7.5Ni₁₀C ${u_{17.5}}^{[53]}$ . (a) XRD patterns; (b) potentiodynamic

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图 6. 锆基块体非晶合金基于不同脉冲宽度的理论温度演化以及烧蚀坑的SEM图像^[64]

Fig. 6. Theoretical temperature evolution in a Zr-based bulk amorphous alloys at different pulse durations and SEM images of ablation pits^[64]

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图 7. 经不同激光器电流加工的表面的润湿性比较^[68]。(a) 未加工;(b) 28.5 A;(c) 29 A;(d) 30 A

Fig. 7. Comparison of wettability of surface processed by different laser currents^[68].(a) Unprocessed; (b) 28.5 A; (c) 29 A; (d) 30 A

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姚燕生, 唐建平, 张亚超, 胡衍雷, 吴东. 非晶合金激光制造技术研究进展[J]. 中国激光, 2021, 48(2): 0202012. Yansheng Yao, Jianping Tang, Yachao Zhang, Yanlei Hu, Dong Wu. Development of Laser Fabrication Technology for Amorphous Alloys[J]. Chinese Journal of Lasers, 2021, 48(2): 0202012.

非晶合金激光制造技术研究进展下载： 1827次特邀综述

图 1. 不同体系的厘米级块体非晶合金锭^[6]。(a) Pd-Cu-Ni-P; (b) Zr-Al-Ni-Cu; (c) Cu-Zr-Al-Ag;(d) Ni-Pd-P-B

Fig. 1. Centimeter-sized bulk amorphous alloy ingots of different systems^[6]. (a) Pd-Cu-Ni-P; (b) Zr-Al-Ni-Cu; (c) Cu-Zr-Al-Ag; (d) Ni-Pd-P-B

图 2. 选区激光熔化成形非晶构件及其非晶态结构的表征^[14]。(a)成形的非晶构件;(b) 快淬薄带、粉末以及成形构件的XRD图

Fig. 2. Amorphous alloy components formed by selective laser melting and the characterization of amorphous structure^[14]. (a) Amorphous alloy components formed by selective laser melting; (b) XRD patterns of as-spun ribbon, powders, and formed components

图 3. Ti6Al4V合金与增材制造锆基块体非晶合金的磨损行为、生物相容性的比较^[25]。(a)摩擦因数;(b)磨损率; (c)动电位极化曲线; (d)体外细胞培养情况

Fig. 3. Comparison of wear behavior and biocompatibility between Ti6Al4V alloy and 3D printed Zr-based bulk amorphous alloy^[25]. (a) Friction coefficient; (b) wear rate; (c) potentiodynamic polarization curves; (d) in vitro cell culture

图 4. 焊接锆基非晶合金在不同扫描速度下的宏观二维图与结构特征^[30]。(a)(b) 2m·min^-1; (c) 4m·min^-1; (d) 8m·min^-1; (e) 各数字对应区域的XRD图

Fig. 4. Macroscopic planar views and structural characteristics of welded Zr-based amorphous alloy at different scanning speeds^[30].(a)(b) 2m·min^-1; (c) 4m·min^-1; (d) 8m·min^-1; (e) XRD patterns of the corresponding regions

图 5. Zr₆₅Al_7.5Ni₁₀Cu_17.5多层非晶合金涂层第7层、第4层和第1层的结构特征与耐腐蚀性能测试结果^[53]。(a) XRD图;(b)动电位极化曲线

Fig. 5. Structural characteristics and corrosion resistance test results of the seventh layer, fourth layer, and first layer of multi-layer amorphoous alloy coating Zr₆₅Al_7.5Ni₁₀C ${u_{17.5}}^{[53]}$ . (a) XRD patterns; (b) potentiodynamic

图 6. 锆基块体非晶合金基于不同脉冲宽度的理论温度演化以及烧蚀坑的SEM图像^[64]

Fig. 6. Theoretical temperature evolution in a Zr-based bulk amorphous alloys at different pulse durations and SEM images of ablation pits^[64]

图 7. 经不同激光器电流加工的表面的润湿性比较^[68]。(a) 未加工;(b) 28.5 A;(c) 29 A;(d) 30 A

Fig. 7. Comparison of wettability of surface processed by different laser currents^[68].(a) Unprocessed; (b) 28.5 A; (c) 29 A; (d) 30 A

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图 1. 不同体系的厘米级块体非晶合金锭[6]。(a) Pd-Cu-Ni-P; (b) Zr-Al-Ni-Cu; (c) Cu-Zr-Al-Ag;(d) Ni-Pd-P-B

Fig. 1. Centimeter-sized bulk amorphous alloy ingots of different systems[6]. (a) Pd-Cu-Ni-P; (b) Zr-Al-Ni-Cu; (c) Cu-Zr-Al-Ag; (d) Ni-Pd-P-B

图 2. 选区激光熔化成形非晶构件及其非晶态结构的表征[14]。(a)成形的非晶构件;(b) 快淬薄带、粉末以及成形构件的XRD图

Fig. 2. Amorphous alloy components formed by selective laser melting and the characterization of amorphous structure[14]. (a) Amorphous alloy components formed by selective laser melting; (b) XRD patterns of as-spun ribbon, powders, and formed components

图 3. Ti6Al4V合金与增材制造锆基块体非晶合金的磨损行为、生物相容性的比较[25]。(a)摩擦因数;(b)磨损率; (c)动电位极化曲线; (d)体外细胞培养情况

Fig. 3. Comparison of wear behavior and biocompatibility between Ti6Al4V alloy and 3D printed Zr-based bulk amorphous alloy[25]. (a) Friction coefficient; (b) wear rate; (c) potentiodynamic polarization curves; (d) in vitro cell culture

图 4. 焊接锆基非晶合金在不同扫描速度下的宏观二维图与结构特征[30]。(a)(b) 2m·min-1; (c) 4m·min-1; (d) 8m·min-1; (e) 各数字对应区域的XRD图

Fig. 4. Macroscopic planar views and structural characteristics of welded Zr-based amorphous alloy at different scanning speeds[30].(a)(b) 2m·min-1; (c) 4m·min-1; (d) 8m·min-1; (e) XRD patterns of the corresponding regions

图 5. Zr65Al7.5Ni10Cu17.5多层非晶合金涂层第7层、第4层和第1层的结构特征与耐腐蚀性能测试结果[53]。(a) XRD图;(b)动电位极化曲线

Fig. 5. Structural characteristics and corrosion resistance test results of the seventh layer, fourth layer, and first layer of multi-layer amorphoous alloy coating Zr65Al7.5Ni10Cu17.5[53]. (a) XRD patterns; (b) potentiodynamic

图 6. 锆基块体非晶合金基于不同脉冲宽度的理论温度演化以及烧蚀坑的SEM图像[64]

Fig. 6. Theoretical temperature evolution in a Zr-based bulk amorphous alloys at different pulse durations and SEM images of ablation pits[64]

图 7. 经不同激光器电流加工的表面的润湿性比较[68]。(a) 未加工;(b) 28.5 A;(c) 29 A;(d) 30 A

Fig. 7. Comparison of wettability of surface processed by different laser currents[68].(a) Unprocessed; (b) 28.5 A; (c) 29 A; (d) 30 A

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非晶合金激光制造技术研究进展下载： 1827次特邀综述

图 1. 不同体系的厘米级块体非晶合金锭^[6]。(a) Pd-Cu-Ni-P; (b) Zr-Al-Ni-Cu; (c) Cu-Zr-Al-Ag;(d) Ni-Pd-P-B

Fig. 1. Centimeter-sized bulk amorphous alloy ingots of different systems^[6]. (a) Pd-Cu-Ni-P; (b) Zr-Al-Ni-Cu; (c) Cu-Zr-Al-Ag; (d) Ni-Pd-P-B

图 2. 选区激光熔化成形非晶构件及其非晶态结构的表征^[14]。(a)成形的非晶构件;(b) 快淬薄带、粉末以及成形构件的XRD图

Fig. 2. Amorphous alloy components formed by selective laser melting and the characterization of amorphous structure^[14]. (a) Amorphous alloy components formed by selective laser melting; (b) XRD patterns of as-spun ribbon, powders, and formed components

图 3. Ti6Al4V合金与增材制造锆基块体非晶合金的磨损行为、生物相容性的比较^[25]。(a)摩擦因数;(b)磨损率; (c)动电位极化曲线; (d)体外细胞培养情况

Fig. 3. Comparison of wear behavior and biocompatibility between Ti6Al4V alloy and 3D printed Zr-based bulk amorphous alloy^[25]. (a) Friction coefficient; (b) wear rate; (c) potentiodynamic polarization curves; (d) in vitro cell culture

图 4. 焊接锆基非晶合金在不同扫描速度下的宏观二维图与结构特征^[30]。(a)(b) 2m·min^-1; (c) 4m·min^-1; (d) 8m·min^-1; (e) 各数字对应区域的XRD图

Fig. 4. Macroscopic planar views and structural characteristics of welded Zr-based amorphous alloy at different scanning speeds^[30].(a)(b) 2m·min^-1; (c) 4m·min^-1; (d) 8m·min^-1; (e) XRD patterns of the corresponding regions

图 5. Zr₆₅Al_7.5Ni₁₀Cu_17.5多层非晶合金涂层第7层、第4层和第1层的结构特征与耐腐蚀性能测试结果^[53]。(a) XRD图;(b)动电位极化曲线

Fig. 5. Structural characteristics and corrosion resistance test results of the seventh layer, fourth layer, and first layer of multi-layer amorphoous alloy coating Zr₆₅Al_7.5Ni₁₀C ${u_{17.5}}^{[53]}$ . (a) XRD patterns; (b) potentiodynamic

图 6. 锆基块体非晶合金基于不同脉冲宽度的理论温度演化以及烧蚀坑的SEM图像^[64]

Fig. 6. Theoretical temperature evolution in a Zr-based bulk amorphous alloys at different pulse durations and SEM images of ablation pits^[64]

图 7. 经不同激光器电流加工的表面的润湿性比较^[68]。(a) 未加工;(b) 28.5 A;(c) 29 A;(d) 30 A

Fig. 7. Comparison of wettability of surface processed by different laser currents^[68].(a) Unprocessed; (b) 28.5 A; (c) 29 A; (d) 30 A