光学元件狭缝柔性调节机构的设计与分析 -

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光学元件狭缝柔性调节机构的设计与分析

doi:10.3788/CO.20171006.0790

董世则^{1, 2,},
郭抗¹,
李显凌^1,,,
陈华男¹,
张德福¹

1.
中国科学院长春光学精密机械与物理研究所应用光学国家重点实验室超精密光学工程研究中心, 吉林长春 130033
2.
中国科学院大学, 北京 100049

基金项目:

国家科技重大专项（02专项）资助项目2009ZX02205

国家自然科学基金资助项目61504142

详细信息

作者简介:
董世则(1991-), 男, 河南濮阳人, 硕士研究生, 主要从事光学精密仪器结构设计及微位移方面的研究。E-mail:dongshize14@mails.ucas.ac.cn
李显凌(1974—)，男，辽宁沈阳人，副研究员，主要从事精密机械及精密光学仪器结构等方面的研究

通讯作者:
李显凌, E-mail：lixianling@sklao.ac.cn

中图分类号:TH701;TH703
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- 被引次数:0
出版历程
- 收稿日期:2017-06-11
- 修回日期:2017-08-13
- 刊出日期:2017-12-01

Design and analysis of adjustment mechanism with slit diaphragm flexures for optical elements

1.
Engineering Research Center of Extreme Precision Optics, State Key Laboratory of Applied Optics, Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, Changchun 130033, China
2.
University of Chinese Academic of Sciences, Beijing 100049, China

Funds:

National Science and Technology Major Project of China2009ZX02205

National Natural Science Foundation of China61504142

More Information

Corresponding author:LI Xian-ling, E-mail:lixianling@sklao.ac.cn

摘要

摘要:设计了一种狭缝柔性结构的光学元件调节机构，使光学元件在具备较高调节精度的同时，保持较高的导向精度。采用弹性力学应力函数法分析了狭缝柔性结构的刚度，以径向刚度与轴向刚度的比值为目标函数，对狭缝柔性结构尺寸参数进行了优化，在不超过柔性结构材料屈服应力等约束条件下，刚度比最优值达到1 573.6，较大的刚度比值可以减小调节机构的耦合位移，从而提高机构的导向精度。该结构加工装配方便，可实现三自由度（ θ _x- θ _y- Z）调节。对优化后的柔性结构进行仿真分析，结果表明：径向刚度与轴向刚度比值的仿真值为1 660.4，解析值与仿真值误差为5.23%，证明了刚度分析方法的有效性。优化后的结构，轴向调节行程为2.09 mm，绕x轴偏转角度调节行程为±16.6 mrad，绕y轴偏转角度调节行程可达到±14.4 mrad，满足光学元件调节的大行程要求。
- 光刻物镜/
- 调节机构/
- 狭缝柔性结构/
- 刚度比/
- 导向精度
Abstract:An adjustment mechanism with slit diaphragm flexures is designed to keep the optical elements with higher guide precision while maintaining higher accuracy of adjustment. The stiffness of the slit diaphragm flexures structure is analyzed using the elastic mechanics stress function method. The ratio of the radial stiffness to the axial rigidity is taken as the objective function to optimize the dimension parameters of the slit diaphragm flexures structure. Under the condition of not exceeding the yield stress of the flexible structure material, the optimal value of the stiffness ratio reaches 1 573.6. A larger stiffness ratio can reduce the coupling displacement of the adjustment mechanism, so as to improve the guide accuracy of the mechanism. This mechanism is easily fabricated and assembled, and allows adjustment of three degree of freedom ( θ _x- θ _y- Z). The stiffness of the slit diaphragm flexure is simulated and analyzed. The results show that the ratio of radial stiffness to axial stiffness is 1 660.4, and the error between analytical value and simulation value is 5.23%, which proves the validity of the stiffness analysis method. The optimized structure has an axial adjustment stroke of 2.09 mm, an adjustment stroke of ±16.6 mrad about the x-axis deflection angle and a ±14.4 mrad deflection angle about the y-axis, which satisfies the large stroke adjustment requirement of the optical element.
- lithographic objective/
- adjustment mechanism/
- slit diaphragm flexures/
- stiffness ratio/
- guide precision

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图 1柔性调节机构示意图

Figure 1.Structure schematic diagram of the flexible mechanism

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图 2驱动器分布示意图

Figure 2.Sketch of evenly distributed actuators

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图 3两端固支圆弧形梁

Figure 3.Curved beam with fixed ends

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图 4驱动力与轴向位移关系

Figure 4.Force vs. the axial displacement

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图 5驱动力与径向位移关系

Figure 5.Force vs. the radial displacement

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图 6狭缝柔性结构轴向位移变形云图

Figure 6.Axial deformation of the slit diaphragm flexures

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图 7狭缝柔性结构Von Mises应力云图

Figure 7.Von Mises stress of the slit diaphragm flexures

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图 8狭缝柔性结构绕X轴偏转调节变形云图

Figure 8.Angle deformation of the slit diaphragm flexures around onXaxis

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图 9狭缝柔性结构绕Y轴偏转调节变形云图

Figure 9.Angle deformation of the slit diaphragm flexures around onYaxis

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表 1最优化参数值

Table 1.Value of optimized parameters

b/mm	h/mm	d/mm	r_f/mm	α/(°)	maxf(X)
13	1.25	1	139.5	16	1 573.6

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表 2狭缝柔性结构性能参数解析值与仿真值比照

Table 2.Comparison between performance parameters of the slit diaphragm flexures and simulation valves

	The axial stiffness/(N·mm^-1)	The radial stiffness/(N·mm^-1)	The stiffness ratio
The theoretical value	14.61	2 2996	1 573.6
The simulation value	14.34	23 809	1 660.4
The relative tolerance(%)	1.92	3.41	5.23

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