Yuki Gao scite author profile

The use of non-metallic pipes and composite components that are low-cost, durable, light-weight, and resilient to corrosion is growing rapidly in various industrial sectors such as oil and gas industries in the form of non-metallic composite pipes. While these components are still prone to damages, traditional non-destructive testing (NDT) techniques such as eddy current technique and magnetic flux leakage technique cannot be utilized for inspection of these components. Microwave imaging can fill this gap as a favorable technique to perform inspection of non-metallic pipes. Holographic microwave imaging techniques are fast and robust and have been successfully employed in applications such as airport security screening and underground imaging. Here, we extend the use of holographic microwave imaging to inspection of multiple concentric pipes. To increase the speed of data acquisition, we utilize antenna arrays along the azimuthal direction in a cylindrical setup. A parametric study and demonstration of the performance of the proposed imaging system will be provided.

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Near-Field Imaging of Dielectric Components Using an Array of Microwave Sensors

Gao¹,

Ravan²,

Amineh³

2022

SSRN Journal

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Near-Field Imaging of Dielectric Components Using an Array of Microwave Sensors

2023

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Microwave imaging is a high-resolution, noninvasive, and noncontact method for detecting hidden defects, cracks, and objects with applications for testing nonmetallic components such as printed circuit boards, biomedical diagnosis, aerospace components inspection, etc. In this paper, an array of microwave sensors designed based on complementary split ring resonators (CSRR) are used to evaluate the hidden features in dielectric media with applications in nondestructive testing and biomedical diagnosis. In this array, each element resonates at a different frequency in the range of 1 GHz to 10 GHz. Even though the operating frequencies are not that high, the acquisition of evanescent waves in extreme proximity to the imaged object and processing them using near-field holographic imaging allows for obtaining high-resolution images. The performance of the proposed method is demonstrated through simulation and experimental results.

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Thickness Profile Estimation of Fluid-Carrying Non-Metallic Pipes

Shah

Gao

Ravan

et al. 2022

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Yuki Gao

Quantitative Defect Size Evaluation in Fluid-Carrying Nonmetallic Pipes

Fast, Robust, and Low-Cost Microwave Imaging of Multiple Non-Metallic Pipes

Near-Field Imaging of Dielectric Components Using an Array of Microwave Sensors

Near-Field Imaging of Dielectric Components Using an Array of Microwave Sensors

Thickness Profile Estimation of Fluid-Carrying Non-Metallic Pipes

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