Research on Stress Field Detection of Building Blasting Environment Based on Infrared Digital Holography

LAI Benlin; ZHANG Yongan; ZHANG Yaping; TIAN Li; ZHAO Danlu; HUANG Junhao; WANG Gang; ZHAO Hang

Volume 45 Issue 1

Jan. 2023

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Infrared Technology > 2023 > 45(1): 102-109.

LAI Benlin, ZHANG Yongan, ZHANG Yaping, TIAN Li, ZHAO Danlu, HUANG Junhao, WANG Gang, ZHAO Hang. Research on Stress Field Detection of Building Blasting Environment Based on Infrared Digital Holography[J]. Infrared Technology , 2023, 45(1): 102-109.

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Research on Stress Field Detection of Building Blasting Environment Based on Infrared Digital Holography

1.
School of Science, Kunming University of Science and Technology, Kunming 650504, China
2.
Northern Night Vision Technology Co., Ltd, Kunming 650214, China

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Received Date: July 25, 2022
Revised Date: September 12, 2022

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Abstract

Abstract

Infrared digital holography has strong real-time performance, is not easily disturbed by visible light, and can be detected in complex environments. It is widely used in special fields. For example, dust aerosols in a blasting environment have strong absorption and scattering effects on visible light, and infrared light at the wavelength of the "atmospheric window" in the infrared band is less affected by aerosols. This advantage has been combined with digital holography. A smooth cement plate of moderate size was fixed on a three-dimensional force application frame as the research object, and the infrared digital holography method was used to change the dust concentration in the environment. The stress field changes of smooth cement plates under different pressures were measured, and the feasibility of this method was verified by comparing holograms and phase differences. Visible light digital holography was used as a control experiment. The results show that infrared digital holography can measure the force application point, relative pressure, and stress influence area of the stress field in an environment of high-concentration dust and realize real-time, nondestructive, and full-field detection, while visible digital holography in this environment is poor or even unable to complete the detection. The method proposed in this paper significantly expands the practicality of the stress detection method based on digital holographic interferometry.
- infrared digital holography,
- blasting environment,
- stress field,
- real-time detection

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References

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Research on Stress Field Detection of Building Blasting Environment Based on Infrared Digital Holography

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