宋宇轩

   2021年6月博士毕业于浙江工业大学化工过程机械专业，同年7月博士后入站浙江工业大学机械工程博士后流动站，2023年10月出站。同年11月以朝晖特聘副研究员入职浙江工业大学机械工程学院动力工程及工程热物理学科。长期从事高温压力容器结构完整性与高效智能检测装备研发工作，主持国家基金青年项目、浙江省基金青年项目，多项校企合作科研项目，以第一作者/通讯作者发表SCI论文10余篇，授权发明专利6项。

         主讲《计算机辅助工程分析》、《化工设备设计基础》与《过程装备有限元技术》等本科生课程，并负责实践课程《化工设备设计基础课程设计》与《压力容器课程设计》。

1.董贺展，2025，浙江省优秀硕士研究生。

1.主持，虑及微区变形协调的高温气冷堆焊接接头蠕变疲劳损伤机制与表征方法研究，国家自然科学基金青年项目C类，2024.01-2026.12，30万，在研；

2. 主持，第三代镍基单晶材料蠕变疲劳微观损伤表征方法及本构模型研究，浙江省自然科学基金青年项目，2024.01-2026.12，10万，在研；

3. 主持，特种设备先进材料及检测技术研究开发中心，企业委托横向，2024.12-至今，400万，在研；

4. 主持，基于泄露风险的含缺陷管道在线预处理装置研发及示范应用，企业委托横向，2024.01-2025.11，10.5万，在研；

5. 主持，舟山石化分馏塔维修加固结构强度和稳定性分析，企业委托横向，2022.01-2022.03，9.7万，结题；

6. 参与（2/3），基于纳米压入技术的焊接接头蠕变疲劳损伤评定及寿命预测方法研究，浙江省自然科学基金重点项目，2022.01-2024.12，30万，结题；

7. 参与（2/7），高风险工业管道损伤智能检测技术装备研发及应用示范，国家重点研发计划子课题，2023.11-2026.11，60万，在研。

        以第一/通讯作者发表SCI JCR 2区及以上论文14篇，其中相关领域顶刊《International Journal of Fatigue》等ZJUT TOP 100论文3篇，授权发明专利2项，获国际结构完整性学术研讨会（ISSI）最佳论文奖（全球6位）与机械工程学会-压力容器分会优秀青年论文奖，担任《International Journal of Plasticity》、《International Journal of Fatigue》与《International Journal of Mechanical Science》等期刊审稿人。

[1]     Chen H, Song Y X, Zhang T H, et al. Structure relaxation effect on hardness and shear transformation zone volume of a NiNb metallic glassy film[J]. Journal of Non-Crystalline Solids, 2018, 499: 257-263.

[2]     Li X, Song Y, Ding Z, et al. A modified correlation between KJIC and Charpy V-notch impact energy of Chinese SA508-III steel at the upper shelf[J]. Journal of Nuclear Materials, 2018, 505: 22-29.

[3]     Ma Y, Song Y, Huang X, et al. Testing effects on shear transformation zone size of metallic glassy films under nanoindentation[J]. Micromachines, 2018, 9(12): 636.

[4]     Ma Y, Huang X, Song Y, et al. Orientation-independent yield stress and activation volume of dislocation nucleation in LiTaO3 single crystal by nanoindentation[J]. Materials, 2019, 12(17): 2799.

[5]     Ding Z Y, Song Y X, Ma Y, et al. Nanoindentation investigation on the size-dependent creep behavior in a Zr-Cu-Ag-Al bulk metallic glass[J]. Metals, 2019, 9(5): 613.

[6]     Ma Y, Song Y, Zhang T. Revealing nanoindentation size-dependent creep behavior in a La-based metallic glassy film[J]. Nanomaterials, 2019, 9(12): 1712.

[7]     Ma Y, Huang X, Song Y, et al. Room-temperature creep behavior and activation volume of dislocation nucleation in a LiTaO3 single crystal by nanoindentation[J]. Materials, 2019, 12(10): 1683.

[8]     Song Y, Huang X, Gao Z, et al. Nanoindentation creep behavior of RPV’s weld joint at room temperature[J]. Mechanics of Time-Dependent Materials, 2020, 24(3): 253-263.

[9]     Gao Z, Song Y, Pan Z, et al. Nanoindentation investigation on the creep behavior of P92 steel weld joint after creep-fatigue loading[J]. International Journal of Fatigue, 2020, 134: 105506.

[10]Song Y, Qin F, Chen J, et al. On the microstructural evolution and room‐temperature creep behaviour of 9% Cr steel weld joint under prior creep–fatigue interaction[J]. Fatigue & Fracture of Engineering Materials & Structures, 2021, 44(2): 444-460.

[11]Song Y, Ma Y, Pan Z, et al. Nanoindentation characterization of creep-fatigue interaction on local creep behavior of P92 steel welded joint[J]. Chinese Journal of Mechanical Engineering, 2021, 34(1): 131.

[12]Song Y, Dai Y, Gao Z, et al. Probing strain rate effect on the creep–fatigue fracture mechanism of 9% Cr steel‐welded joint via nanoindentation characterization[J]. Fatigue & Fracture of Engineering Materials & Structures, 2021, 44(12): 3320-3333.

[13]Song Y, Ma Y, Chen H, et al. The effects of tensile and compressive dwells on creep-fatigue behavior and fracture mechanism in welded joint of P92 steel[J]. Materials Science and Engineering: A, 2021, 813: 141129.

[14]Song Y, Pan Z, Chen J, et al. The effects of prior creep–fatigue on the strain rate sensitivity of a P92 welded joint[J]. Journal of Materials Science, 2021, 56(11): 7111-7128.

[15]Li Y, Song Y, Liu P, et al. The Investigation of the Fracture Behavior of a Chinese 9% Cr Steel Welded Joint under Creep-Fatigue Interactive Loading[J]. Applied Sciences, 2021, 11(21): 9983.

[16]Pan Z, Li Y, Song Y, et al. Effects of strain rate on the tensile and creep-fatigue properties of 316H stainless steel[J]. International Journal of Pressure Vessels and Piping, 2022, 200: 104774.

[17]Lu C, Ding J, Song Y, et al. Revealing thickness dependence of hardness, strain rate sensitivity, and creep resistance of nano-crystalline magnesium/titanium multilayers by nanoindentation[J]. Materials Research Express, 2022, 9(4): 046401.

[18]Song Y, Yu T, Chen H, et al. Understanding the relation between creep-fatigue fracture mechanisms and intergranular dislocation accommodation of a high chromium steel using nanoindentation characterization[J]. International Journal of Fatigue, 2022, 159: 106796.

[19]Song Y, Pan Z, Li Y, et al. Nanoindentation characterization on the temperature-dependent fracture mechanism of Chinese 316H austenitic stainless steel under creep-fatigue interaction[J]. Materials Characterization, 2022, 186: 111806.

[20]Song Y, Pan Z, Yu T, et al. Nanoindentation characterization on competing propagation between the transgranular and intergranular cracking of 316H steel under creep‐fatigue loading[J]. Fatigue & Fracture of Engineering Materials & Structures, 2023, 46(6): 2258-2271.

[21]Zhang L, Song Y, Wang X, et al. A study of fatigue property enhancement of 1045 steel processed by surface mechanical rolling treatment with an emphasis on residual stress influence[J]. International Journal of Fatigue, 2024, 189: 108560.

[22]Jin W, Han Y, Song Y, et al. An Investigation on Fatigue Strengthening Mechanism of 316L Stainless Steel Welded Joint by Surface Mechanical Rolling Treatment[J]. Fatigue & Fracture of Engineering Materials & Structures, 2025, 48(11): 4687-4700.

[23]Yu T, Wang Z, Gao Z, et al. A modified creep life prediction method based on nanoindentation characterisation for P92 steel[J]. Materials at High Temperatures, 2025, 42(5-6): 329-344.

[24]Shen Z, Cai Z, Wang H, et al. A Modified Fatigue Life Prediction Model for Cyclic Hardening/Softening Steel[J]. Materials, 2025, 18(14): 3274.

[25]Jin Z, Cai Z, Gu X, et al. A Study of the Creep-Fatigue Damage Mechanism of a P92 Welded Joint Using Nanoindentation Characterization[J]. Metals, 2025, 15(1): 53.

[26]Zhang L, Song Y, Wang X, et al. A study of fatigue behavior of 310S stainless steel after surface mechanical rolling treatment[J]. International Journal of Fatigue, 2025: 109387.

[27]Wang Z, Wang Y, Song Y, et al. An experimental study on stress-dependent creep behaviors and void evolution of Ni-based single-crystal alloy [J]. Journal of Materials Science, 2026

[28]Yu T, Wang Z, Lin Y, et al. An experimental study on stress-dependent creep behaviors and microstructural evolutions of 316H stainless steel by nanoindentation characterization[J]. Engineering Failure Analysis, 2026: 110825.

[29]Song Y, Suo X, Lin Y, et al. Nanoindentation investigation on the relation between local mechanical properties and cyclic hardening/softening behavior of 310S stainless steel[J].Fatigue & Fracture of Engineering Materials & Structures, 2026.

  EI检索论文

[1]     董贺展,余婷,宋宇轩,等. 核电316H奥氏体不锈钢疲劳损伤机制与温度敏感性研究[J].材料导报,2026,40(02):193-200. 

Ø 中文论文（与前面不重复）

[1]     宋宇轩,余婷,秦富饶,等. P92钢及其焊接接头的蠕变-疲劳寿命预测[J].压力容器,2021,38(11):26-35.

[2]     宋宇轩,陈海云,丁振宇,等.缠绕气瓶最佳自紧压力分析与缠绕层表面损伤安全评估[C]//中国机械工程学会压力容器分会,合肥通用机械研究院.压力容器先进技术—第九届全国压力容器学术会议论文集.浙江工业大学化工机械设计研究所;杭州市特种设备检测研究院;,2017:604-610.

[3]     戴志伟,王志强,宋宇轩,等.油套管特殊螺纹接头上扣扭矩工程计算方法构建[J].机电工程,2026.