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摘要:为了实现尺寸为1 200 mm×484 mm的大长宽比长条形空间反射镜的无热装配,减小反射镜面形精度受热应力的影响,本文对环氧胶(GHJ-01(Z))胶层厚度对反射镜面形的影响及胶层在静、动力学载荷下的应力进行了研究。首先,介绍了现有的几种基于胡克定律推导的无热粘结厚度方程及其假设条件,并推导了带有锥度的背部盲孔反射镜无热粘结胶层厚度的方程,得出无热粘结胶层厚度曲线;然后,建立了6种不同胶层厚度的反射镜组件模型并进行了分析与比较。通过分析,在+5℃温升工况下,反射镜胶层厚度为0.07 mm时具有最好的面形精度,其RMS值0.0178 λ,其检测方向在自重作用下的面形精度RMS值为0.0173 λ,一阶频率为220.17 Hz;最后对胶层无热化设计后的反射镜组件进行了振动试验和粘结剂剪切强度试验,分析与试验表明:反射镜组件一阶频率为216.4 Hz,与有限元分析结果相对误差为1.71%;满足动静态刚度要求;同时,在动力学载荷下该厚度胶层的应力均小于其固化后的抗剪强度,安全裕度为2.46;各项指标满足设计要求。Abstract:In order to realize the athermal assembling of rectangular special mirror with large dimension of 1 200 mm×485 mm, and reduce the effect of hot stress on primary mirror's surface figure precision, the effect of epoxy thickness on the surface figure accuracy of the mirror and the stress of epoxy under static and dynamic conditions are researched. First of all, several already existing athermal adhesive thickness equations obtained based on Hooke's law are introduced. The athermal adhesive thickness equations of the primary mirror which has blind holes with taper in the back is developed, and the curve of athermal adhesive thickness is obtained. Then six modes of mirror with different adhesive thickness are made. The result of analysis shows that the mirror's RMS are 0.0178 λ(optical value) and 0.0173 λ(gravity in detecting's directions) under 5℃ uniform temperature rise when the epoxy thickness is 0.07 mm. Finally, vibration tests of mirror components and drawing test of epoxy are conducted. Analysis and experiment results indicate that its first order frequency is 216.4 Hz and the error between them is 1.71%. The maximum stress of epoxy under dynamic conditions is smaller than the shear strength which is 30.2 MPa, obtained through drawing test of Epoxy, and the safety margin is 2.46. All indicators meet the design requirements.
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图 4(a)反射镜装配剖面图;(b)反射镜组件有限元模型;(c)镶嵌件有限元模型;(d)局部放大胶层模型
Figure 4.(a)Section of primary mirror assembly; (b)finite element model; (c)finite element model of the mosaic; (d)enlarged adhesive model
图 5不同反射镜模型粘接处最大应力拟合曲线
Figure 5.Fitting curve of the maximum stresses in different mirror mode
图 7不同胶层厚度反射镜RMS的拟合曲线
Figure 7.Fitting curve of primary mirror′s RMS with different adhesive thicknesses
图 8胶厚0.07 mm的反射镜在热载荷下的面形图
Figure 8.Cloud chart of primary mirror′s surface figure with 0.07 mm adhesive
图 11Y向随机试验前的0.2 g扫频曲线
Figure 11.0.2 g sweep curve ofYdirection before random vibration test
图 13粘结剂(GHJ-01(Z))粘接镶嵌件的拉伸试验
Figure 13.Tensile test of the glue(GHJ-01(Z)) bonding the inlay of mirror component
表 1材料属性参数
Table 1.Material property parameters
ρ/(kg·mm-3) E/MPa α/(10-6·℃-1) ν SiC 3.05×10-6 3.30×105 2.7 0.27 4J32 8.10×10-6 1.41×105 2.4 0.25 Epoxy 1.22×10-6 158.62(20 ℃) 72(≧20 ℃) 0.495 TC4 4.40×10-6 1.09×105 9.1 0.34 
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表 2反射镜在重力场下的分析结果
Table 2.Analysis results of mirror under gravity
X向 Y向 Z向 RMS 0.0062λ 0.0173λ 0.0355λ PV 0.0268λ 0.0843λ 0.1643λ 下载:
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表 3反射镜组件的模态
Table 3.Mode of primary mirror assembly
阶数 频率/Hz 振型 1 220.17 反射镜绕Z轴摆动 2 246.56 反射镜绕Y轴摆动 3 253.05 反射镜沿Y向振动 下载:
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表 4反射镜组件中胶层的峰值应力和最大应力
Table 4.Peak and maximum stress of epoxy in the primary mirror assembly
X向 Y向 Z向 正弦峰值应力/MPa 9.2 10.9 12.3 最大随机应力/MPa 5.1 6.9 8.6 下载:
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表 5随机振动试验的力学条件
Table 5.Mechanical condition of random vibration test
频率范围/Hz 功率谱密度/(g2·Hz-1) 总均方根值/(gRMS) 10~60 +3.0 dB/oct 60~200 0.12 200~300 ↘ 8.2 300~800 0.04 800~2 000 -6.0 dB/oct 下载:
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