Equivalent modeling and evaluation of molars using point-contact higher kinematic pair based on occlusal dynamic analysis.

Wenlong Qin; Ming Cong; Xiang Ren; Dong Liu

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Equivalent modeling and evaluation of molars using point-contact higher kinematic pair based on occlusal dynamic analysis.

Author: Wenlong QIN ¹ ; Ming CONG ¹ ; Xiang REN ² ; Dong LIU ¹
Author Information

1. School of Mechanical Engineering, Dalian University of Technology, Dalian, Liaoning 116024, P.R.China.
2. College of Stomatology, Dalian Medical University, Dalian, Liaoning 116044, P.R.China.
Publication Type:Journal Article
Keywords: equivalent modeling; finite element method; molar; occlusal dynamics; point-contact higher kinematic pair
MeSH: Biomechanical Phenomena; Bite Force; Humans; Mastication; Molar
From: Journal of Biomedical Engineering 2020;37(4):614-621
CountryChina
Language:Chinese
Abstract: As a representative part of the oral system and masticatory robot system, the modeling method of the dental model is an important factor influencing the accuracy of the multi-body dynamic model. Taking the right first molars of the masticatory robot as the research object, an equivalent model, point-contact higher kinematic pair composed of v-shaped surface and sphere surface, was proposed. Firstly, the finite element method was used to analyze the occlusal dynamics of the original model in three static contact cases (intrusive contact, centric occlusion, and extrusive contact) and one dynamic chewing case, and the expected bite force was obtained. Secondly, the Hertz contact model was adopted to establish the analytical expression of the bite force of the equivalent model in three static contact cases. The normal vectors and contact stiffness in the expression were designed according to the expected bite force. Finally, the bite force performance of the equivalent model in three static contact cases and one dynamic chewing case was evaluated. The results showed that the equivalent model could achieve the equivalent bite force of 8 expected items in the static contact cases. Meanwhile, the bite force in the early and late stages of the dynamic chewing case coincides well with the original model. In the middle stage, a certain degree of impact is introduced, but it can be weakened by subsequent trajectory planning. The equivalent modeling scheme of the dental model proposed in this paper further improves the accuracy of the dynamic model of the multi-body system. It provides a new idea for the dynamic modeling of other complex human contacts.