Structural design of gradient porous dental implant based on orthogonal test

doi:10.7518/hxkq.2023.2023188

Abstract

Abstract:

Objective To solve the current problems of loosening and dislodging caused by the high elastic modulus of solid implants, we attempted to study a gradient porous dental implant that can lower the stress concentration and reduce the elastic modulus. Methods SolidWorks software was utilized to design the abutment and mechanical structure of the gradient porous implant. The mechanical properties of the gradient porous implant were evaluated by an orthogonal experimental design from four aspects: pore shape, pore diameter, porous layer height, and circumferential distribution. ANSYS software was used to evaluate the distribution of Von-Mises stress in the implant and its surrounding bone tissues under different structural combination parameters to derive the optimal combination of gradient porous implant parameters. Results The effects of the four factors, namely, pore shape, pore diameter, porous layer height and pore distribution, on the maximum Von-Mises stress on the implant were as follows. As the pore shape became smaller and the circumferential distribution decreased, the Von-Mises stress decreased significantly. The pore diameter went from 500 μm to 600 μm and then to 700 μm. The Von-Mises stress decreased and then increased. It increased with the increase in the height of the porous layer. Conclusion The final optimal combination of parameters for the gradient porous implant was as follows: square pore shape, pore diameter of 600 μm, porous layer height of 3 mm, and quadratic step in pore distribution.

Key words: gradient porous, dental implants, elastic modulus, orthogonal experiment, finite element analysis

CLC Number:

R 783.1

Wang Liangtao, Li Shan, Lu Doudou, Chen Zheng.. Structural design of gradient porous dental implant based on orthogonal test[J]. West China Journal of Stomatology, 2023, 41(6): 647-652.

Figures/Tables 9

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References 22

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材料	弹性模量/GPa	泊松比	屈服强度/MPa
种植体（Ti6Al4V）	110	0.3	800
皮质骨	13.7	0.3	130
Ⅱ类松质骨	5.5	0.3	50

水平	孔形	孔径/μm	多孔层高度/mm	孔分布
1	圆形	500	3	四分布
2	六边形	600	4	六分布
3	正方形	700	5	八分布

试验号	孔形	孔径/μm	多孔层高度/mm	孔分布
1	圆形	500	3	四分布
2	圆形	600	4	六分布
3	圆形	700	5	八分布
4	圆形	700	5	四分布
5	六边形	500	4	八分布
6	六边形	600	5	四分布
7	六边形	700	3	六分布
8	六边形	500	4	六分布
9	正方形	500	5	六分布
10	正方形	600	3	八分布
11	正方形	700	4	四分布
12	正方形	500	3	四分布
13	正方形	500	5	八分布
14	正方形	600	3	四分布
15	正方形	600	5	四分布
16	正方形	700	5	八分布

试验号	Von-Mises应力值	试验号	Von-Mises应力值
1	99.98	9	102.31
2	118.56	10	101.31
3	127.62	11	99.53
4	110.59	12	99.98
5	116.32	13	110.66
6	97.89	14	96.86
7	114.42	15	106.66
8	111.55	16	110.16

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