Design of nonlinear locking mechanism for shape memory alloy archwire of miniature orthodontic device_Journal of Biomedical Engineering

Authors：

DAI Qingyuan ¹ , JI Li ^2,3 , HUA Jiahao ¹ , LIANG Zhenyu ¹ , YU Jianwen ⁴ ,  CHEN Taicong ^1,5

1. School of Civil Engineering and Transportation, South China University of Technology, Guangzhou 510640, P. R. China;
2. The First Affiliated Hospital, Sun Yat-sen University, Guangzhou 510080, P. R. China;
3. Guangzhou OO Stomatology Institute, Guangzhou 510080, P. R. China;
4. Guangzhou OO Medical Scientific Limited, Guangzhou 510080, P. R. China;
5. State Key Laboratory of Subtropical Building and Urban Science, Guangzhou 510640, P. R. China;

Corresponding author：

CHEN Taicong, Email: cvchentc@scut.edu.cn

Keywords：

Orthodontic device; Locking mechanics; Shape memory alloy; Orthogonal design of experiment

DOI：

10.7507/1001-5515.202306051

Video：

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The locking mechanism between bracket and shape memory alloy (SMA) archwire in the newly developed domestic orthodontic device is the key to controlling the precise alignment of the teeth. To meet the demand of locking force in clinical treatment, the tightening torque angle of the locking bolt and the required torque magnitude need to be precisely designed. For this purpose, a design study of the locking mechanism is carried out to analyze the correspondence between the tightening torque angle and the locking force and to determine the effective torque value, which involves complex coupling of contact, material and geometric nonlinear characteristics. Firstly, a simulation analysis based on parametric orthogonal experimental design is carried out to determine the SMA hyperelastic material parameters for the experimental data of SMA archwire with three-point bending. Secondly, a two-stage fine finite-element simulation model for bolt tightening and archwire pulling is established, and the nonlinear analysis is converged through the optimization of key contact parameters. Finally, multiple sets of calibration experiments are carried out for three tightening torsion angles. The comparison results between the design analysis and the calibration experiments show that the deviation between the design analysis and the calibration mean value of the locking force in each case is within 10%, and the design analysis method is valid and reliable. The final tightening torque angle for clinical application is determined to be 10° and the rated torque is 2.8 N∙mm. The key data obtained can be used in the design of clinical protocols and subsequent mechanical optimization of novel orthodontic devices, and the research methodology can provide a valuable reference for force analysis of medical devices containing SMA materials.

Citation： DAI Qingyuan, JI Li, HUA Jiahao, LIANG Zhenyu, YU Jianwen, CHEN Taicong. Design of nonlinear locking mechanism for shape memory alloy archwire of miniature orthodontic device. Journal of Biomedical Engineering, 2024, 41(4): 766-774. doi: 10.7507/1001-5515.202306051 Copy

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2.	Wu J L, Liu Y F, Peng W, et al. A biomechanical case study on the optimal orthodontic force on the maxillary canine tooth based on finite element analysis. Journal of Zhejiang University-Science B, 2018, 19(7): 535-546.
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7.	李治国, 闫文刚, 冯海全. 自膨式镍钛合金血管支架安全性能研究. 生物医学工程学杂志, 2020, 37(2): 334-339.
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13.	吴倩, 张彬, 李楠, 等. 三维有限元分析在口腔医学领域的应用及研究进展. 世界最新医学信息文摘, 2019, 19(20): 95-96,99.
14.	华嘉皓, 吉利, 代清源, 等. 矫牙过程托槽致唇颊软组织非线性反应量化分析研究. 生物医学工程学杂志, 2023, 40(2): 295-302.
15.	罗睿, 赵振达, 冷慧杰, 等. 大鼠牙槽骨理想模型的流固耦合数值模拟研究. 生物医学工程学杂志, 2020, 37(1): 87-95.
16.	苏杰华, 刘佳莉, 张端强, 等. 上颌前牙段阻抗中心定位的有限元研究. 生物医学工程学杂志, 2014, 31(5): 994-1000.
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19.	Cai Y. Effects of the insertion of an archwire thin-walled sleeve in accelerating the canine’s translation. Journal of Mechanics in Medicine and Biology, 2020, 20(9): 2040009.
20.	Auricchio F, Taylor R L. Shape-memory alloys: modelling and numerical simulations of the finite-strain superelastic behavior. Computer Methods in Applied Mechanics and Engineering, 1997, 143(1-2): 175-194.
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23.	阎石, 王琦, 王伟. 超弹性形状记忆合金丝力学性能试验. 沈阳建筑大学学报(自然科学版), 2010, 26(3): 458-463.
24.	Zeng Lingqi. Static finite element analysis of three-closed box thin-wall beam based on pseudo-elastic SMA hybrid composite material ANSYS. Journal of Physics: Conference Series, 2021, 1802: 022095.
25.	徐涛, 隋杰英, 魏征. 室温下形状记忆合金丝拉伸力学性能试验研究. 青岛理工大学学报, 2022, 43(1): 31-35.
26.	赵选民. 试验设计方法. 北京: 科学出版社, 2006: 64-122.
27.	今村仙治. SUS303 中実円筒の機械的性質測定のための最適試験条件 (OS9-2 衝撃と種々の測定法//OS9 実験力学における新たな試み), M&M 材料力学カンファレンス, 2007: 367-368.
28.	沈国辉, 陈震, 郭勇, 等. 螺栓节点板抗剪连接的有限元模拟方法研究. 工程力学, 2013, 30(1): 119-125.
29.	钟炜辉, 孟宝, 郝际平. 不同跨度比下腹板双角钢连接抗倒塌性能研究. 工程科学与技术, 2017, 49(4): 86-96.
30.	Elkady O A M, Abu-Oqail A, Ewais E M M, et al. Physico-mechanical and tribological properties of Cu/h-BN nanocomposites synthesized by PM route. Journal of Alloys and Compounds, 2015, 625: 309-317.
31.	Li H, Ramezani M, Li M, et al. Tribological performance of selective laser melted 316L stainless steel. Tribology International, 2018, 128: 121-129.
32.	Levintant-Zayonts N, Starzynski G, Kopec M, et al. Characterization of NiTi SMA in its unusual behaviour in wear tests. Tribology International, 2019, 137: 313-323.

1. Katsikogianni E N, Reimann S, Weber A, et al. A comparative experimental investigation of torque capabilities induced by conventional and active, passive self-ligating brackets. European Journal of Orthodontics, 2015, 37(4): 440-446.
2. Wu J L, Liu Y F, Peng W, et al. A biomechanical case study on the optimal orthodontic force on the maxillary canine tooth based on finite element analysis. Journal of Zhejiang University-Science B, 2018, 19(7): 535-546.
3. Franco É M, Valarelli F P, Fernandes J B, et al. Comparative study of torque expression among active and passive self-ligating and conventional brackets. Dental Press Journal of Orthodontics, 2015, 20(6): 68-74.
4. 冯岩, 董敏, 许潾于. 不同正畸力对上颌尖牙移动速率影响的分析. 口腔医学研究, 2017, 33(4): 420-423.
5. Papageorgiou S N, Sifakakis I, Keilig L, et al. Torque differences according to tooth morphology and bracket placement: a finite element study. European Journal of Orthodontics, 2017, 39(4): 411-418.
6. Otsuka K, Wayman C M. Shape memory materials. Cambridge: Cambridge University Press, 1999: 1-10.
7. 李治国, 闫文刚, 冯海全. 自膨式镍钛合金血管支架安全性能研究. 生物医学工程学杂志, 2020, 37(2): 334-339.
8. Petrini L, Migliavacca F. Biomedical applications of shape memory alloys. Journal of Metallurgy, 2011: 501483.
9. 邢海瑞, 朱明, 崔跃, 等. Ti-Ni合金血管支架的有限元分析及疲劳性能研究. 稀有金属, 2016, 40(10): 976-981.
10. 吉利. 牵引托槽与正畸矫正系统及其矫正方法. 中国, 201510046931. X. 2018-11-9.
11. Fernandes D J, Peres R V, Mendes A M, et al. Understanding the shape-memory alloys used in orthodontics. ISRN Dentistry, 2011, 2011: 132408.
12. 吉利, 陈正, 陈彬, 等. 止锁扩弓非拔牙矫治技术治疗重度牙列拥挤1例并文献复习. 精准医学杂志, 2021, 36(4): 295-298.
13. 吴倩, 张彬, 李楠, 等. 三维有限元分析在口腔医学领域的应用及研究进展. 世界最新医学信息文摘, 2019, 19(20): 95-96,99.
14. 华嘉皓, 吉利, 代清源, 等. 矫牙过程托槽致唇颊软组织非线性反应量化分析研究. 生物医学工程学杂志, 2023, 40(2): 295-302.
15. 罗睿, 赵振达, 冷慧杰, 等. 大鼠牙槽骨理想模型的流固耦合数值模拟研究. 生物医学工程学杂志, 2020, 37(1): 87-95.
16. 苏杰华, 刘佳莉, 张端强, 等. 上颌前牙段阻抗中心定位的有限元研究. 生物医学工程学杂志, 2014, 31(5): 994-1000.
17. Zhou X, Gan Y, Zhao Q, et al. Simulation of orthodontic force of archwire applied to full dentition using virtual bracket displacement method. Int J Numer Method Biomed Eng, 2019, 35(5): e3189.
18. 仵健磊, 刘云峰, 李伯休, 等. 不同牙槽骨有限元模型对牙周膜生物力学响应的影响. 生物医学工程学杂志, 2021, 38(2): 295-302.
19. Cai Y. Effects of the insertion of an archwire thin-walled sleeve in accelerating the canine’s translation. Journal of Mechanics in Medicine and Biology, 2020, 20(9): 2040009.
20. Auricchio F, Taylor R L. Shape-memory alloys: modelling and numerical simulations of the finite-strain superelastic behavior. Computer Methods in Applied Mechanics and Engineering, 1997, 143(1-2): 175-194.
21. Wick A, Vöhringer O, Pelton A R. The bending behavior of NiTi. Journal de Physique IV, 1995, 5(C8): 789-794.
22. DesRoches R, McCormick J, Delemont M. Cyclic properties of superelastic shape memory alloy wires and bars. Journal of Structural Engineering, 2004, 130(1): 38-46.
23. 阎石, 王琦, 王伟. 超弹性形状记忆合金丝力学性能试验. 沈阳建筑大学学报(自然科学版), 2010, 26(3): 458-463.
24. Zeng Lingqi. Static finite element analysis of three-closed box thin-wall beam based on pseudo-elastic SMA hybrid composite material ANSYS. Journal of Physics: Conference Series, 2021, 1802: 022095.
25. 徐涛, 隋杰英, 魏征. 室温下形状记忆合金丝拉伸力学性能试验研究. 青岛理工大学学报, 2022, 43(1): 31-35.
26. 赵选民. 试验设计方法. 北京: 科学出版社, 2006: 64-122.
27. 今村仙治. SUS303 中実円筒の機械的性質測定のための最適試験条件 (OS9-2 衝撃と種々の測定法//OS9 実験力学における新たな試み), M&M 材料力学カンファレンス, 2007: 367-368.
28. 沈国辉, 陈震, 郭勇, 等. 螺栓节点板抗剪连接的有限元模拟方法研究. 工程力学, 2013, 30(1): 119-125.
29. 钟炜辉, 孟宝, 郝际平. 不同跨度比下腹板双角钢连接抗倒塌性能研究. 工程科学与技术, 2017, 49(4): 86-96.
30. Elkady O A M, Abu-Oqail A, Ewais E M M, et al. Physico-mechanical and tribological properties of Cu/h-BN nanocomposites synthesized by PM route. Journal of Alloys and Compounds, 2015, 625: 309-317.
31. Li H, Ramezani M, Li M, et al. Tribological performance of selective laser melted 316L stainless steel. Tribology International, 2018, 128: 121-129.
32. Levintant-Zayonts N, Starzynski G, Kopec M, et al. Characterization of NiTi SMA in its unusual behaviour in wear tests. Tribology International, 2019, 137: 313-323.

Journal of Biomedical Engineering

Design of nonlinear locking mechanism for shape memory alloy archwire of miniature orthodontic device

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