研究生: |
洪聖博 Sheng-Po Hung |
---|---|
論文名稱: |
數位同軸全像微粒循跡測速儀之研發與其於聲射微流體之應用 Development of Digital In-line Holographic Micro Particle Tracking Velocimetry and Its Application in Acoustofluidics |
指導教授: |
田維欣
Wei-Hsin Tien |
口試委員: |
陳品銓
Pin-Chuan Chen 蔣雅郁 Ya-Yu Chiang 曾修暘 Hsiu-Yang Tseng |
學位類別: |
碩士 Master |
系所名稱: |
工程學院 - 機械工程系 Department of Mechanical Engineering |
論文出版年: | 2022 |
畢業學年度: | 110 |
語文別: | 中文 |
論文頁數: | 162 |
中文關鍵詞: | 數位同軸全像顯微鏡 、微粒循跡測速儀 、聲射流 |
外文關鍵詞: | Digital In-line Holographic Microscopy (DIHM), Particle Tracking Velocimetry (PTV), Acoustic streaming |
相關次數: | 點閱:538 下載:15 |
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本研究以數位同軸全像顯微鏡(Digital In-line Holographic Microscopy, DIHM)研發三維流場微粒循跡測速(Particle Tracking Velocimetry, PTV)的量技術,並將之應用於量測以三角形微結構激發 之聲射微流體(acoustofluidics)之三維流場。微流體以微銑削方式製造出壓克力模具,再使用軟微影技術以 PDMS 翻模製成。流道側壁設計有三角形微結構,經壓電片振動後,產生穩態聲射流。在DIHM的開發上,使用Huygens-Fresnel光傳播原理中Rayleigh-Sommerfeld的第一個解,做為微流場全像圖之三維重建理論,並成功於Matlab上研發處理程式,進行全像圖前處理與重建、微粒中尋心、微粒三維位置重建、PTV循跡分析等步驟,將流場中的速度資訊完整呈現。利用電子移動平台與點陣列之校正片,得出本研究之實驗設置可解析之體積約為 555μm×690μm×440μm,其平均放大倍率為8.79倍,標準差為0.047。利用電子移動平台進行深度位置校正之結果得出三維位置不准度x、y位置分別為0.84μm、0.79μm,z位置則為9.03μm。流場速度不准度則為101.51μm/s。本研究中z位置之不准度是主要的誤差來源,來自於全像圖重建時深度方向的微粒影像被拉長的效應。解析三角形微結構周圍的聲射流三維速度場結果顯示,在渦旋中微結構尖端與周圍速度之速度差可達10倍左右,是在先前研究中未能觀測到的微粒速度場變化。最後,透過比較以綠光532nm與藍光450nm雙波長的實驗得知,不同波長的光對於全像圖的影響是重建位置時因為不同波長的光之焦距不同,進而導致色差的產生。重建時會產生 z 方向上的平移,平移約為 13~15μm。
In this study, Digital In-line Holographic Microscopy(DIHM) was used to develop a technique to perform Particle Tracking Velocimetry(PTV) for microscale flows, and was applied to measuring the 3-D flow field in an acoustofluidics induced by a triangular micro-structure. in the three-dimensional flow field. The acoustofluidic device is made using soft lithography with the acrylic mold made by micro-milling and rolling over with PDMS. The triangular micro-structure on the micro channel sidewall oscillates by the vibration of piezoelectric disk to produce a steady-state acoustic streaming flow. For the development of DIHM the first solution of Rayleigh-Sommerfeld in the Huygens-Fresnel light propagation principle was used as the theoratical basis of the three-dimensional reconstruction. A data processing flow based on MATLAB was successfully constructed to perform steps including pre-processing and reconstruction of the hologram, finding the particle center position, reconstruction of the particle 3-D position and PTV analysis to acquire whole-field velocity information in the flow. With the use of the motorised linear stage and calibration target plate for calibration, the current experimental setup can resolve a volume of 555μm×690μm×440μm. The average magnification is 8.79 with a standard deviation of 0.047. The calibration for depth location shows that the uncertainty of x and y positions are and respectively and for the z position. The resulting velocity uncertainty of the flow field is . The major source of error is from the uncertainty of the z position d due to the elongation of the reconstructed particle image in the depth direction. The resolved 3-D velocity field around the triangular micro-structure shows that the velocity difference between the tip and the outer-region of the vortical flow can achieve a ratio of 10, which was not observed in the previous studies. Through the comparison of 532nm and 450nm dual-wavelength experiments, the influence of illumination wavelengths on the holographic image was found to be the chromatic aberration effect due to different focal lengths of the illumination. The chromatic aberration causes a translation about 13~15μm in the resoved z direction when the same magnification is applied.
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