多孔表面结构对立体光固化成型氧化锆疲劳强度的影响

doi:10.19723/j.issn.1671-167X.2025.06.022

摘要/Abstract

摘要：

目的: 研究多孔表面结构对立体光固化成型氧化锆疲劳强度的影响，为3D打印氧化锆种植体表面优化设计提供参考。方法: 通过立体光固化成型技术制备氧化锆试件，根据表面结构分为无孔组、200 μm孔组、400 μm孔组。通过三维激光形貌显微镜及扫描电镜观察其表面微观形貌，测定表面粗糙度、孔隙参数、晶粒尺寸。通过三点弯曲试验检测试件弯曲强度，并进行Weibull分析；通过疲劳试验检测试件的疲劳强度，扫描电镜观察断口，采用X射线衍射仪对疲劳试验前后的试件进行晶相分析，分析疲劳机制。结果: 立体光固化成型无孔组、200 μm孔组及400 μm孔组试件表面孔间粗糙度分别为(0.79±0.09) μm、(0.81±0.16) μm、(0.81±0.09) μm，组间差异无统计学意义；表面晶粒尺寸分别为(324.11±21.38) nm、(308.06±11.34) nm、(311.62±15.02) nm，组间差异无统计学意义。三点弯曲试验结果显示，无孔组三点弯曲强度[(1 030.70±111.71) MPa]显著高于两组多孔组(P＜0.001)，200 μm孔组[(272.04±61.16) MPa]显著高于400 μm孔组[(201.21±25.58) MPa]，P＜0.01。疲劳试验结果显示，无孔组疲劳强度[(702.29±21.62) MPa]显著高于两组多孔组(P＜0.001)，200 μm孔组[(159.57±9.30) MPa]显著高于400 μm孔组[(125.36±6.11) MPa]，P＜0.001。断口分析结果显示，疲劳裂纹源主要为材料内部缺陷、气孔、夹杂及打印层结合处等。疲劳试验前后各组试件之间相比，氧化锆单斜相含量差异均无统计学意义。结论: 表面多孔微观结构会显著降低立体光固化成型氧化锆试件的疲劳强度，且孔径增大可造成疲劳强度下降；未来应着重改进3D打印氧化锆的材料及打印工艺，进一步优化表面结构设计，以提升3D打印氧化锆的力学性能。

关键词: 氧化锆, 多孔, 3D打印, 疲劳强度

Abstract:

Objective: To study the effect of porous surface structure on fatigue strength of zirconia fabricated by stereolithography apparatus (SLA), and to provide reference for the surface design of 3D printed zirconia implants. Methods: Zirconia specimens were fabricated by SLA. According to the surface structure, zirconia specimens were divided into non-porous group, 200 μm group and 400 μm group. The surface morphology was observed by 3D laser morphology microscope and scanning electron microscope, and the surface roughness, pore parameters and grain size were measured. The flexural strength of the specimen was measured by three-point bending test and Weibull analysis was performed. The fatigue strength of the specimens was measured by fatigue test, and the fatigue mechanism was analyzed by fractrography. The crystal phase before and after fatigue test of the specimen was analyzed by X-ray diffraction. Results: The surface roughness of the area between the pores of non-porous group, 200 μm group and 400 μm group was (0.79±0.09) μm, (0.81±0.16) μm and (0.81±0.09) μm, respectively, with no significant difference among them. The surface grain size was (324.11±21.38) nm, (308.06±11.34) nm, (311.62±15.02) nm, respectively, with no significant difference among them. The results of three-point bending test showed that the three-point bending strength of the non-porous group [(1 030.70±111.71) MPa] was significantly higher than that of the porous groups (P < 0.001). The 200 μm group [(272.04±61.16) MPa] was significantly higher than the 400 μm group [(201.21±25.58) MPa] (P < 0.01). The fatigue strength of the non-porous group [(702.29± 21.62) MPa] was significantly higher than that of the porous groups (P < 0.001), and the fatigue strength of the 200 μm group [(159.57±9.30) MPa] was significantly higher than that of the 400 μm group [(125.36±6.11) MPa] (P < 0.001). The fracture analysis results showed that the crack origins were mainly internal defects, air holes, inclusions and the joint of printing layer, etc. There was no significant difference in the content of monoclinic phase before and after fatigue test among all the groups. Conclusion: The surface porous microstructure could significantly reduce the fatigue strength of the zirconia specimens, and the larger pore size showed the lower fatigue strength. In the future, the material and printing process of 3D printing zirconia should be improved, and the surface structure design should be further optimized to improve the mechanical properties of 3D printing zirconia.

Key words: Zirconia, Porous, 3D printing, Fatigue strength

中图分类号:

R783.1

赵健霄, 丁茜, 李文锦, 马全诠, 兰一笑, 张磊, 韩建民. 多孔表面结构对立体光固化成型氧化锆疲劳强度的影响[J]. 北京大学学报（医学版）, 2025, 57(6): 1165-1173.

Jianxiao ZHAO, Qian DING, Wenjin LI, Quanquan MA, Yixiao LAN, Lei ZHANG, Jianmin HAN. Effect of porous surface structure on fatigue strength of 3D printed zirconia[J]. Journal of Peking University (Health Sciences), 2025, 57(6): 1165-1173.

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Group	Ra/μm	Rq/μm	Rz/μm
Non-porous	0.79±0.09	0.98±0.21	8.17±1.02
200 μm	0.81±0.16	1.06±0.18	8.79±1.48
400 μm	0.81±0.09	1.05±0.11	8.31±0.89

Group	Design value of pore diameter/μm	Measured value of pore diameter/μm, ${\bar x}$±s	Design value of pore depth/μm	Measured value of pore depth/μm, ${\bar x}$±s	Design value of pore-pitch/μm	Measured value of pore-pitch/μm，${\bar x}$±s
200 μm	200.00	200.02±6.15	400.00	379.35±11.22^**	430.00	429.08±9.31
400 μm	400.00	366.48±6.88^**	600.00	572.84±29.35^*	860.00	883.99±9.41^**

Group	Three-point flexural strength/MPa, ${\bar x}$±s	Fatigue strength/MPa, ${\bar x}$±s	Characteristic strength/MPa	95%CI	Weibull modulus	95%CI
Non-porous	1 030.70±111.71	702.29±21.62	1 080.10	1 027.12-1 135.91	10.61	7.23-15.84
200 μm	272.04±61.16	159.57±9.30	296.40	264.97-331.55	4.80	3.29-6.99
400 μm	201.21±25.58	125.36±6.11	211.68	201.25-222.66	10.50	6.89-15.99

Group	Before fatigue test		Unbroken after fatigue test		Broken after fatigue test
Group	X_m	V_m	X_m	V_m	X_m	V_m
Non-porous	9.51%	12.09%	10.78%	13.67%	10.42%	13.23%
200 μm	10.01%	12.72%	11.17%	14.14%	10.43%	13.25%
400 μm	9.64%	12.27%	9.69%	12.34%	10.42%	13.22%