CN112730072A - 气体压力下圆形预应力薄膜最大挠度的确定方法 - Google Patents

气体压力下圆形预应力薄膜最大挠度的确定方法 Download PDF

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CN112730072A
CN112730072A CN202011432310.2A CN202011432310A CN112730072A CN 112730072 A CN112730072 A CN 112730072A CN 202011432310 A CN202011432310 A CN 202011432310A CN 112730072 A CN112730072 A CN 112730072A
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孙俊贻
张颀
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Abstract

本发明公开了一种气体压力下圆形预应力薄膜最大挠度的确定方法,其特征在于:对杨氏弹性模量为E、泊松比为v、半径为a、厚度为h、预应力为σ0、最初平坦且周边固定夹紧的圆形预应力薄膜施加气体压力q,让该圆形预应力薄膜在气体压力作用下产生轴对称变形,那么基于该圆形预应力薄膜轴对称变形的静力平衡分析,利用气体压力q的测量值,就可以确定出该圆形预应力薄膜轴对称变形后的最大挠度wm

Description

气体压力下圆形预应力薄膜最大挠度的确定方法
技术领域
本发明涉及一种气体压力作用下周边固定夹紧的圆形预应力薄膜的最大挠度的确定方法。
背景技术
气体压力作用下周边固定夹紧的圆形预应力薄膜的轴对称变形问题的解析解,在许多工程技术领域都有应用,例如,用来研究薄膜/基层系统的粘附能测量、以及研制各种仪器仪表和各类传感器等。从文献查新的结果来看,迄今为止还没有气体压力作用下周边固定夹紧的圆形预应力薄膜的轴对称变形问题的解析研究成果,仅有横向均布载荷作用下周边固定夹紧的圆形预应力薄膜轴对称变形问题的解析研究成果,例如发明专利“一种确定均布载荷下预应力圆薄膜最大挠度值的方法”(专利号:ZL201410238568.7)就是在这个解析研究成果的基础上提出的。众所周知,横向均布载荷作用下圆形预应力薄膜的轴对称变形问题与气体压力作用下圆形预应力薄膜的轴对称变形问题是两个不同的力学问题,因为横向均布载荷与气体压力的作用方向是不同的,即,横向均布载荷始终垂直于最初平坦的圆形薄膜的几何中面,而气体压力则始终垂直于轴对称变形的圆形薄膜的表面,由此可见,在圆形薄膜轴对称变形的过程中,横向均布载荷作用在薄膜上的方向是保持不变的,而气体压力作用在薄膜上的方向是随着圆形薄膜的轴对称变形而变化的。显而易见,如果能够获得气体压力作用下圆形预应力薄膜的轴对称变形问题的解析解,这无疑是一项非常有价值的工作,可以为工程技术领域提供更大的研发空间。
发明内容
本发明致力于气体压力作用下周边固定夹紧的圆形预应力薄膜的轴对称变形问题的解析研究,基于气体压力作用下周边固定夹紧的圆形预应力薄膜轴对称变形的静力平衡分析,得到了该轴对称变形问题的解析解,并在此基础上给出了气体压力下圆形预应力薄膜最大挠度的确定方法。
气体压力下圆形预应力薄膜最大挠度的确定方法:对杨氏弹性模量为E、泊松比为v、半径为a、厚度为h、预应力为σ0、最初平坦且周边固定夹紧的圆形预应力薄膜施加气体压力q,让该圆形预应力薄膜在气体压力作用下产生轴对称变形,那么基于该圆形预应力薄膜轴对称变形的静力平衡分析,就可以得到所施加的气体压力q与该圆形预应力薄膜轴对称变形后的最大挠度wm之间的解析关系
Figure BDA0002826934210000011
其中,
Figure BDA0002826934210000021
Figure BDA0002826934210000022
Figure BDA0002826934210000023
Figure BDA0002826934210000024
Figure BDA0002826934210000025
Figure BDA0002826934210000026
而b0的值由方程
Figure BDA0002826934210000027
Figure BDA0002826934210000028
Figure BDA0002826934210000029
Figure BDA00028269342100000210
Figure BDA0002826934210000031
Figure BDA0002826934210000032
Figure BDA0002826934210000033
d0=b0
Figure BDA0002826934210000034
Figure BDA0002826934210000035
Figure BDA0002826934210000036
Figure BDA0002826934210000037
Figure BDA0002826934210000041
Figure BDA0002826934210000042
确定。
这样,只要准确测得气体压力q的值,就可以把该圆形预应力薄膜轴对称变形后的最大挠度wm确定下来,其中,a、h、wm的单位均为毫米(mm),σ0、E、q的单位均为牛顿每平方毫米(N/mm2),而v、b0、b2、b4、b6、b8、b10、b12、c2、c4、c6、c8、c10、c12、d0、d2、d4、d6、d8、d10、d12均为无量纲的量。
附图说明
图1为气体压力作用下周边固定夹紧的圆形预应力薄膜轴对称变形的示意图,其中,1是轴对称变形后的圆形预应力薄膜,2是夹紧装置,3是最初平坦的圆形预应力薄膜的几何中面,4是支座,而a表示圆形预应力薄膜的半径和夹紧装置的内半径,o表示坐标系的原点,r表示径向坐标,w表示横向坐标(也表示轴对称变形后的圆形预应力薄膜上任一点的挠度),q表示作用在圆形预应力薄膜表面上的气体压力,wm表示圆形预应力薄膜轴对称变形后的最大挠度。
具体实施方式
下面结合具体案例对本发明的技术方案作进一步的说明:
如图1所示,对杨氏弹性模量E=7.84N/mm2、泊松比v=0.47、半径a=20mm、厚度h=0.2mm、预应力σ0=3N/mm2、最初平坦且周边固定夹紧的圆形预应力薄膜施加气体压力q,让该圆形预应力薄膜在气体压力作用下产生轴对称变形,测得气体压力q=0.05N/mm2,那么采用本发明所给出的方法,由方程
Figure BDA0002826934210000051
Figure BDA0002826934210000052
Figure BDA0002826934210000053
Figure BDA0002826934210000054
Figure BDA0002826934210000055
Figure BDA0002826934210000056
Figure BDA0002826934210000057
d0=b0
Figure BDA0002826934210000058
Figure BDA0002826934210000061
Figure BDA0002826934210000062
Figure BDA0002826934210000063
Figure BDA0002826934210000064
Figure BDA0002826934210000065
得到b0=0.5920715以及b2=-0.1671145、b4=-0.0255077、b6=-0.0075440、b8=-0.0027627、b10=-0.0011289、b12=-0.0004934、d0=0.5920715、d2=-0.1581024、d4=-0.0307167、d6=-0.0107168、d8=-0.0044513、d10=-0.0020137、d12=-0.0009585,再由方程
Figure BDA0002826934210000066
Figure BDA0002826934210000067
Figure BDA0002826934210000071
Figure BDA0002826934210000072
Figure BDA0002826934210000073
Figure BDA0002826934210000074
得到c2=-0.2692897、c4=-0.0380040、c6=-0.0110184、c8=-0.0040089、c10=-0.0016350、c12=-0.0007146,最后由方程
Figure BDA0002826934210000075
确定出该圆形预应力薄膜在气体压力q=0.05N/mm2作用下的最大挠度为wm=6.5053058mm。

Claims (1)

1.气体压力下圆形预应力薄膜最大挠度的确定方法,其特征在于:对杨氏弹性模量为E、泊松比为v、半径为a、厚度为h、预应力为σ0、最初平坦且周边固定夹紧的圆形预应力薄膜施加气体压力q,让该圆形预应力薄膜在气体压力作用下产生轴对称变形,那么基于该圆形预应力薄膜轴对称变形的静力平衡分析,利用气体压力q的测量值,由方程
Figure FDA0002826934200000011
Figure FDA0002826934200000012
Figure FDA0002826934200000013
Figure FDA0002826934200000014
Figure FDA0002826934200000015
Figure FDA0002826934200000016
Figure FDA0002826934200000017
d0=b0
Figure FDA0002826934200000021
Figure FDA0002826934200000022
Figure FDA0002826934200000023
Figure FDA0002826934200000024
Figure FDA0002826934200000025
Figure FDA0002826934200000026
确定b0以及b2、b4、b6、b8、b10、b12、d0、d2、d4、d6、d8、d10、d12的值,然后由方程
Figure FDA0002826934200000027
Figure FDA0002826934200000028
Figure FDA0002826934200000029
Figure FDA0002826934200000031
Figure FDA0002826934200000032
Figure FDA0002826934200000033
确定c2、c4、c6、c8、c10、c12的值,最后由方程
Figure FDA0002826934200000034
确定该圆形预应力薄膜轴对称变形后的最大挠度wm,其中,a、h、wm的单位均为毫米(mm),σ0、E、q的单位均为牛顿每平方毫米(N/mm2),而v、b0、b2、b4、b6、b8、b10、b12、c2、c4、c6、c8、c10、c12、d0、d2、d4、d6、d8、d10、d12均为无量纲的量。
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113720689A (zh) * 2021-08-17 2021-11-30 重庆大学 气体压力下与刚性板接触的圆薄膜的最大应力的确定方法

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113720689A (zh) * 2021-08-17 2021-11-30 重庆大学 气体压力下与刚性板接触的圆薄膜的最大应力的确定方法

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