基于单缝衍射的简支梁挠曲度法测量固体杨氏模量实验探究

doi:10.14139/i.cnki.cn22-1228.2024.06.004

摘要
相关文章
推荐阅读
Metrics

下载:

PDF (2137KB)
输出: BibTeX | EndNote (RIS)

摘要

杨氏模量测量一直是大学物理实验中的一个很重要的实验项目,本文利用单缝衍射装置将简支梁的挠曲度转化为狭缝缝宽的变化量,从而得出梁体的杨氏模量。为提高装置的测量精度和数字化程度,采用 CCD 相机对衍射光斑进行拍摄,并利用数值软件对拍摄图片进行处理得到衍射光斑的宽度和狭缝宽度,从而得到待测物的杨氏模量。该测量方案实验原理清晰合理,实验测量精度较高,同时将力学与光学进行交叉融合,能有效拓展学生思维能力,培养学生创新能力,使学生更深入理解光的衍射原理及杨氏模量的测量方法;同时本实验使用数值软件对图像进行处理而得到实验结果,使实验操作更加高效智能。

	服务
	把本文推荐给朋友
	加入引用管理器
	E-mail Alert
	RSS
	（）
	作者相关文章
	王双莹
	蔡　昭
	景锐平

关键词: 夫琅禾费衍射杨氏模量图像处理

Abstract:

The experimental project of Young’s modulus measurement is very important in the college physics experiment. In this paper ,the deflection of a simply supported beam is transformed into the change of the width of the slit by means of a single slit diffraction deviec ,and the Young modulus of the beam is obtained. In order to improve the measuring precision and digital degree of the device ,a CCl camera is used to photograph the difiraction spot, and use numerical sot ware to process the photographed pictures to get the width of the diffraction spot and the slit width, so as to get the Young modulus of the object to be measured. The experimental principle of this measurement scheme is clear and reasonable ,and the experimental measurement accuracy is high. Meanwhile , the cross-fertilisation of mechanics and optics can elfectively expand students thinking ability and innovation ability, make students understand the principle of light diffraction and the measurement method of Young modulus more deeply ; at the same time ,the experimental results are obtained by using the numerical software to process the images , which makes the experimental operation more efficient and intelligent.

Key words: fraunhofer diffraction Young’s modulus image processing

出版日期: 2024-12-25 发布日期: 2024-12-25 整期出版日期: 2024-12-25

ZTFLH:

O 436.1

引用本文:

王双莹 , 蔡　昭 , 景锐平 . 基于单缝衍射的简支梁挠曲度法测量固体杨氏模量实验探究 [J]. 大学物理实验, 2024, 37(6): 19-24.
WANG Shuangying, CAl Zhao, JlING Ruiping. Experimental Study on Measurement of Young’s Modulus of Solid by Simply Supported Beam Deflection Method Based on Single Slit Diffraction . Physical Experiment of College, 2024, 37(6): 19-24.

链接本文:

https://dawushiyan.jlict.edu.cn/CN/10.14139/i.cnki.cn22-1228.2024.06.004 或 https://dawushiyan.jlict.edu.cn/CN/Y2024/V37/I6/19

[1]	赵金雨, 罗逸文, 何　晴 , 梁衍瑞 , 黎俊晨 , 翁嘉文 . 变栅距光栅的衍射效应与特性分析 [J]. 大学物理实验, 2024, 37(4): 43-50.
[2]	岳伊帆 , 胡亚华 , 李俊成 , 孟劲舟 , 马玉彬 , 张　敏 , 桂　兆 . 基于位置敏感器件的杨氏模量测量 [J]. 大学物理实验, 2024, 37(2): 65-69.
[3]	马鸣远, 张树峰, 李　萍 . 基于数字图像处理的几何光学法测量液体浓度 [J]. 大学物理实验, 2024, 37(2): 100-103.
[4]	刘维慧 , 梁润泽 , 赵泉昕 , 卓朝博 , 苗永平 . 双光源干涉法测量液态薄膜厚度 [J]. 大学物理实验, 2024, 37(1): 31-36.
[5]	颜利芬, 黄运米, 黄晓虹, 王振国. 基于 Matlab GUI 的拉伸法测杨氏弹性模量实验的数据处理 [J]. 大学物理实验, 2023, 36(5): 112-115.
[6]	谢鑫鑫 , 赖盛英, 王慧琴 , 闫然 , 樊伟征 . 利用梯形液膜干涉法实现液体浓度的自动检测 [J]. 大学物理实验, 2023, 36(4): 10-16.
[7]	徐佳丽, 代　伟 , 张宇琪, 李万鑫, 杨　成, 张　欣. 拉伸法杨氏模量实验装置的改进 [J]. 大学物理实验, 2023, 36(3): 59-62.
[8]	肖林轩, 杨阳, 王晓威, 闫涵, 吴峰, 李晓兰 . 斜双镜光杠杆法测量金属丝杨氏模量 [J]. 大学物理实验, 2023, 36(1): 54-58.
[9]	罗天娇 , 吴幸锴 , 孙微微 , 侯丽华 . 基于Ｍａｔｌａｂ的迈克尔逊微小位移测量 [J]. 大学物理实验, 2022, 35(5): 96-99.
[10]	陈水桥, 蔡力 , 陈丰, 陈志博 , 苏婷琳, 颜欣 , 张作成. 液晶空间光调节杨氏双缝干涉法透明介质折射率的优化测量 [J]. 大学物理实验, 2022, 35(3): 41-46.
[11]	刘惠萍, 商祥年, 程凯. 基于 Matlab 的夫琅禾费衍射实验仿真研究 [J]. 大学物理实验, 2022, 35(3): 99-101.
[12]	李鹏宇, 胡翠莹, 高洪悦, 姚金林, 张少梅, 张进娟, 刘维慧, 苗永平. 基于角度传感技术的杨氏模量实验仪研制 [J]. 大学物理实验, 2022, 35(2): 55-69.
[13]	张胜海, 杨晓娜. 基于光功率计监视的杨氏模量测量及不确定度分析 [J]. 大学物理实验, 2022, 35(2): 102-105.
[14]	马堃. 基于拉伸法测量金属丝杨氏模量的实验研究 [J]. 大学物理实验, 2020, 33(1): 17-20.

[1]	. [J]. Physical Experiment of College, 2020, 33(1): 0 .
[2]	. [J]. Physical Experiment of College, 2020, 33(1): 0 .
[3]	WU Ming, ZENG Hong, ZHANG Wenpeng, ZHANG Yuanwei, DAI Zhenbing. Theoretical and Experimental Research of A zimuthal-Radial Pendulum [J]. Physical Experiment of College, 2020, 33(1): 1 -6 .
[4]	LIU Weiwei, SUN Qing, LIU Chenglin. Research on Selection of Critical Magnetization Current for Measuring Charge-Mass Ratio of Electron by Magnetron Controlling [J]. Physical Experiment of College, 2020, 33(1): 7 -9 .
[5]	DENG Li, LIU Yang, ZHANG Hangzhong, ZHOU Kewei, ZHAO guoru, WEI luanyi. MATLAB simulation of Fourier transform of Gaussian beam and the spatial filtering effects basing on 4F optical imaging system [J]. Physical Experiment of College, 2020, 33(1): 10 -16 .
[6]	MA Kun. Experiment Study on the Measuring Young' s Modulus by Stretching [J]. Physical Experiment of College, 2020, 33(1): 17 -20 .
[7]	FEI Xianxiang, CHEN Chunlei, WANG Wenhua, SHI Wenqing, HUANG Cunyou. Design of Lens Group Focal Length Measurement System Based on Object-Image Parallax Comparison [J]. Physical Experiment of College, 2020, 33(1): 21 -24 .
[8]	LI Chunjiang, LI Luyu, YANG Jinglei, LI Tingrong, XIANG Wenli. A New Method for Simple and Rapid Measurement of Refractive Index [J]. Physical Experiment of College, 2020, 33(1): 25 -28 .
[9]	WANG Cuiping, YAO Mengyu, YE Liu, LI Aixia, ZHANG Ziyun, DAI Peng. Progress and Applications of Electron Spin Resonance in Biology [J]. Physical Experiment of College, 2020, 33(1): 29 -33 .
[10]	CHEN Yingmo, SHEN Siyi, WANG Jie. Study on the Characteristics of Silicon Photocells [J]. Physical Experiment of College, 2020, 33(1): 34 -36 .

Viewed

Full text

Abstract

Cited

Shared

Discussed