Qingyuan Dai, Li Ji, Jiahao Hua, Zhenyu Liang, Jianwen Yu, Taicong Chen
{"title":"[Design of nonlinear locking mechanism for shape memory alloy archwire of miniature orthodontic device].","authors":"Qingyuan Dai, Li Ji, Jiahao Hua, Zhenyu Liang, Jianwen Yu, Taicong Chen","doi":"10.7507/1001-5515.202306051","DOIUrl":null,"url":null,"abstract":"<p><p>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.</p>","PeriodicalId":39324,"journal":{"name":"生物医学工程学杂志","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-08-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11366461/pdf/","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"生物医学工程学杂志","FirstCategoryId":"1087","ListUrlMain":"https://doi.org/10.7507/1001-5515.202306051","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"Medicine","Score":null,"Total":0}
引用次数: 0
Abstract
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.
在新开发的国产正畸装置中,托槽与形状记忆合金(SMA)弓丝之间的锁定机制是控制牙齿精确排列的关键。为满足临床治疗中对锁定力的需求,需要对锁定螺栓的紧固扭矩角度和所需扭矩大小进行精确设计。为此,我们对锁定机构进行了设计研究,分析了拧紧扭矩角度与锁定力之间的对应关系,并确定了有效扭矩值,其中涉及接触、材料和几何非线性特性的复杂耦合。首先,针对三点弯曲 SMA 弓丝的实验数据,基于参数正交实验设计进行仿真分析,确定 SMA 超弹性材料参数。其次,建立了螺栓拧紧和弓丝牵引的两阶段精细有限元仿真模型,并通过优化关键接触参数收敛非线性分析。最后,针对三种拧紧扭转角度进行了多组校准实验。设计分析与校准实验的对比结果表明,设计分析与校准平均值的锁力偏差均在 10%以内,设计分析方法有效可靠。最终确定临床应用的拧紧扭矩角度为 10°,额定扭矩为 2.8 N∙mm。所获得的关键数据可用于新型正畸装置的临床方案设计和后续的机械优化,研究方法可为含有 SMA 材料的医疗装置的受力分析提供有价值的参考。