种植体螺丝入路孔道内封洞树脂所受应力的有限元研究

doi:10.13591/j.cnki.kqyx.2025.06.001

摘要/Abstract

摘要：

目的采用三维有限元法比较种植修复体螺丝入路孔道内不同厚度封洞树脂所受的应力差异。方法利用计算机辅助设计软件建立下颌第一磨牙位点处种植牙三维有限元模型,设计不同厚度(1、2、3、4、5 mm)的封洞树脂模型,对其施加200 N的静态载荷,分析不同厚度的封洞树脂所受等效应力和剪应力情况。结果在一定范围内,树脂所受最大等效应力和最大剪应力值大小随着厚度的增加而减小。在厚度1 mm时,树脂所受最大等效应力和最大剪应力分别为23.85、11.82 MPa;在厚度2 mm时,树脂所受最大等效应力和最大剪应力分别为18.75、9.73 MPa;在厚度3 mm时,树脂所受最大等效应力和最大剪应力分别为17.46、9.04 MPa。当树脂厚度>3 mm时,其所受应力趋于稳定。在厚度4 mm时,树脂所受最大等效应力和最大剪应力分别为17.38、9.04 MPa;在厚度5 mm时,树脂所受最大等效应力和最大剪应力分别为17.18、8.85 MPa。结论当封洞树脂达到一定厚度时,其所受应力较小且稳定。这为临床上减少因封洞树脂应力疲劳所引起的种植修复后并发症提供新的设计策略。

关键词: 螺丝入路孔道, 封洞树脂, 三维有限元法

Abstract:

Objective To compare the stress difference of the resin with different thicknesses in the screw access hole using three-dimensional finite element method. Methods A three-dimensional finite element model of the implant at the site of the mandibular first molar was established by computer aided design (CAD) software. A static load of 200 N was applied to the resin models with different thicknesses(1, 2, 3, 4, 5 mm) to analyze the effect of thickness on the von Mises stress and shear stress of the resin. Results In a certain range, the maximum von Mises stress and the maximum shear stress of the resin decreased with the increase of the thickness. At the thickness of 1mm, the maximum von Mises stress and shear stress of the resin were 23.85 MPa and 11.82 MPa, respectively. When the thickness was 2 mm, the maximum von Mises stress and shear stress of the resin were 18.75 MPa and 9.73 MPa respectively. At the thickness of 3 mm, the maximum von Mises stress and shear stress of the resin were 17.46 MPa and 9.04 MPa, respectively. When the thickness of the resin was more than 3 mm, the stress on it was in a stable level trend. When the thickness was 4 mm, the maximum von Mises stress and shear stress of the resin were 17.38 MPa and 9.04 MPa, respectively. When the thickness was 5 mm, the maximum von Mises stress and maximum shear stress of the resin were 17.18 MPa and 8.85 MPa, respectively. Conclusion When the resin reaches a certain thickness, the stress is small and stable. This study provides a new design strategy for reducing the complications after implant restoration caused by stress fatigue of the resin.

Key words: screw approach hole, hole sealing resin, three-dimensional finite element method

中图分类号:

R783.4

李非璠, 吴美琪, 毕梦霏, 沈铭. 种植体螺丝入路孔道内封洞树脂所受应力的有限元研究[J]. 口腔医学, 2025, 45(6): 401-405.

LI Feifan, WU Meiqi, BI Mengfei, SHEN Ming. Finite element study on the stress of hole sealing resin in screw approach of dental implant[J]. Stomatology, 2025, 45(6): 401-405.

图/表 4

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材料	杨氏模量/MPa	泊松比
骨皮质	13 700	0.30
骨松质	1 370	0.30
种植体、基台、中央螺丝	115 000	0.35
牙冠	210 000	0.31
树脂	20 000	0.24
特氟龙	300	0.41