Korean Journal of Optics and Photonics (한국광학회지)

Optical Society of Korea (한국광학회)
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Diameter Measurement of Cylindrical Objects by Non-Contact Method

비접촉식 방법에 의한 원통형 물체의 지름 측정

  • Published : 2005.06.01
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Abstract

Although there are many ways to measure the diameter of a cylindrical object, in this study, the diameter of a cylindrical objects were measured by the geometric optical method and interference-diffraction method which are two kinds of tipical non-contact methods. In geometric optical method, the curved laser beam is formed on the cylindrical surface by spreading the inclined laser beam using the cylindrical lens. The curve is captured by CCD camera and the diameter is calculated by geometry. And the interference and diffraction patterns of investigated cylindrical objects are analyzed in interference-diffraction method. In this study, the cylindrical objects, whose diameters are $0.05\;mm\;\~\;100.50\;mm$ were measured by the geometric optical method and interference-diffraction method. The results show that in each method, the relative errors of the measurement are within $2\%$ and $1\%$, respectively and these non-contact methods can be applied in the quick measurement of many objects.

원통형 물체의 지름을 측정하는 방법에는 여러 가지가 있지만 본 연구에서는 두 가지 비접촉식 방법인 기하광학적 방법과 간섭${\cdot}$회절 방법으로 원통형 물체의 지름을 측정하였다. 기하광학적인 방법은 원통형 렌즈를 이용하여 기울인 레이저 광선을 원통형 물체의 옆면에 비추어 나타나는 곡선을 CCD 카메라로 포착하고 이 곡선을 기하학적인 방법으로 계산하는 것이며 간섭${\cdot} $회절에 의한 방법은 스크린에 나타난 물체에 의한 레이저광의 간섭${\cdot}$회절무늬를 측정하고 분석하는 방법이다. 버니어 캘리퍼스로 측정한 평균 지름이 $0.05\;mm\;\~\;100.50\;mm$ 인 원통형 물체를 기하광학적 방법과 간섭${\cdot}$회절 방법으로 측정한 결과 각각의 상대오차가 $2\%$$1\%$범위 이내였고 다량의 물체 지름을 신속히 측정하는데 응용될 수 있음을 확인하였다.

Keywords

References

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