光电工程
光電工程
광전공정
OPTO-ELECTRONIC ENGINEERING
2013年
10期
17-21
,共5页
朱猛%龙宁波%张昊%黄战华
硃猛%龍寧波%張昊%黃戰華
주맹%룡저파%장호%황전화
电涡流传感器%散斑相关%显微成像%线性区间
電渦流傳感器%散斑相關%顯微成像%線性區間
전와류전감기%산반상관%현미성상%선성구간
eddy current sensor%speckle correlation%micro imaging%linear interval
为了精确的测量电涡流传感器的距离-电压输出线性区间和线性位移精度,本文采用了显微散斑相关法对位移进行标定。首先,利用精度为5μm位移平台进行位移调节,得到位移和电涡流传感器输出电压的线性区间。然后,在线性区间内进行密集采样,通过显微照相系统采集散斑图,利用散斑相关法求出位移,得到更高精度的位移-电压曲线。分析了显微散斑照相的检测流程与检测精度;讨论了散斑尺寸对测量的影响。设计了测量光路参数:采用40×显微物镜配合20×读数显微镜可以实现64.5×的放大倍率。对40铬材料进行了位移-电压曲线标定实验,实验结果证明:本系统可以实现高精度的电涡流传感器位移标定,测量精度达到0.09μm,要实现更高精度的标定可以提高显微系统的放大倍率。
為瞭精確的測量電渦流傳感器的距離-電壓輸齣線性區間和線性位移精度,本文採用瞭顯微散斑相關法對位移進行標定。首先,利用精度為5μm位移平檯進行位移調節,得到位移和電渦流傳感器輸齣電壓的線性區間。然後,在線性區間內進行密集採樣,通過顯微照相繫統採集散斑圖,利用散斑相關法求齣位移,得到更高精度的位移-電壓麯線。分析瞭顯微散斑照相的檢測流程與檢測精度;討論瞭散斑呎吋對測量的影響。設計瞭測量光路參數:採用40×顯微物鏡配閤20×讀數顯微鏡可以實現64.5×的放大倍率。對40鉻材料進行瞭位移-電壓麯線標定實驗,實驗結果證明:本繫統可以實現高精度的電渦流傳感器位移標定,測量精度達到0.09μm,要實現更高精度的標定可以提高顯微繫統的放大倍率。
위료정학적측량전와류전감기적거리-전압수출선성구간화선성위이정도,본문채용료현미산반상관법대위이진행표정。수선,이용정도위5μm위이평태진행위이조절,득도위이화전와류전감기수출전압적선성구간。연후,재선성구간내진행밀집채양,통과현미조상계통채집산반도,이용산반상관법구출위이,득도경고정도적위이-전압곡선。분석료현미산반조상적검측류정여검측정도;토론료산반척촌대측량적영향。설계료측량광로삼수:채용40×현미물경배합20×독수현미경가이실현64.5×적방대배솔。대40락재료진행료위이-전압곡선표정실험,실험결과증명:본계통가이실현고정도적전와류전감기위이표정,측량정도체도0.09μm,요실현경고정도적표정가이제고현미계통적방대배솔。
In order to measure the curves of distance and output voltage for eddy current sensor, a speckle correlation method is proposed. Firstly, the linear interval is measured by the displacement platform with precision of 5um. Secondly, congestion sampling is taken out in the linear interval, the speckle pattern under different distance is captured by the micro-imaging system and more precision curves are obtained with displacement calculated by the speckle correlation method. The precision of measurement is analyzed and the influence of speckle size on measurement is also discussed. The micro-imaging system with magnification of 64.5 is designed by combining an objective with 40 magnifications and a reading microscope with 20 magnifications. The experimental object is the 40 chromium and the results show that the proposed system can achieve high precision calibration for eddy current sensor with 0.09μm precision and more precision can be obtained by changing the magnification of the imaging system.