三维有限元法评估牙种植体螺纹设计对冲击载荷中应力分布的影响。

Journal of Dental Biomaterial Pub Date : 2016-06-01
Zarei I, Khajehpour S, Sabouri A, Haghnegahdar Az, Jafari K
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引用次数: 0

摘要

问题陈述:冲击和意外事故被认为是导致牙齿脱落的主要因素,因此对种植体进行分析和设计,使其更能抵抗冲击是非常重要的。有限元法是在工程科学的各个领域中有着广泛应用的重要的数值方法之一。在其广泛的应用中,可以注意到复杂结构中功率分布的研究。目的:本研究的目的是评估几何效应和种植螺纹的类型对其性能的影响;我们还尝试用有限元法来确定产生的应力。材料与方法:本研究通过锥形束ct (Cone Beam computed Tomography, CBCT)对患者进行了骨三维模型的建立。本研究的植入体采用Solid Works软件设计。加载采用显式动态模拟,采用刚体以1mm /s的速度撞击垂直和水平植入;并在ANSYS Workbench软件中计算出皮质骨和骨小梁的最大诱导应力水平。结果:结合本研究的结果,我们发现在设计的样品中,皮质骨层的最大应力出现在第一组(直螺纹),骨小梁层和种植体的最大应力值出现在第二组(锥形螺纹)。结论:由于本研究的局限性,种植体螺纹深度越深,种植体与骨的接触面越大,稳定性越好;此外,螺纹更小、节距更短的种植体对骨的压力更大。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Assessing the Effect of Dental Implants Thread Design on Distribution of Stress in Impact Loadings Using Three Dimensional Finite Element Method.

Assessing the Effect of Dental Implants Thread Design on Distribution of Stress in Impact Loadings Using Three Dimensional Finite Element Method.

Assessing the Effect of Dental Implants Thread Design on Distribution of Stress in Impact Loadings Using Three Dimensional Finite Element Method.

Assessing the Effect of Dental Implants Thread Design on Distribution of Stress in Impact Loadings Using Three Dimensional Finite Element Method.

Statement of problem: Impacts and accidents are considered as the main fac- tors in losing the teeth, so the analysis and design of the implants that they can be more resistant against impacts is very important. One of the important nu- merical methods having widespread application in various fields of engineering sciences is the finite element method. Among its wide applications, the study of distribution of power in complex structures can be noted.

Objectives: The aim of this research was to assess the geometric effect and the type of implant thread on its performance; we also made an attempt to determine the created stress using finite element method.

Materials and methods: In this study, the three dimensional model of bone by using Cone Beam Computerized Tomography (CBCT) of the patient has been provided. The implants in this study are designed by Solid Works software. Loading is simulated in explicit dynamic, by struck of a rigid body with the speed of 1 mm/s to implant vertically and horizontally; and the maximum level of induced stress for the cortical and trabecular bone in the ANSYS Workbench software was calculated.

Results: By considering the results of this study, it was identified that, among the designed samples, the maximum imposed stress in the cortical bone layer occurred in the first group (straight threads) and the maximum stress value in the trabecular bone layer and implant occurred in the second group (tapered threads).

Conclusions: Due to the limitations of this study, the implants with more depth thread, because of the increased contact surface of the implant with the bone, caused more stability; also, the implant with smaller thread and shorter pitch length caused more stress to the bone.

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