Gamma scattering scanning of concrete block for detection of voids

TL;DR

This study demonstrates a gamma scattering non-destructive evaluation technique to detect and characterize voids in concrete blocks with high sensitivity and spatial resolution, using a PC-controlled system and a reconstruction algorithm.

Contribution

The paper introduces a gamma back-scattering method with a novel reconstruction algorithm for detecting and locating voids in concrete, enhancing NDE capabilities.

Findings

Void detection with better than 0.1% statistical accuracy

High sensitivity to density changes in concrete

Effective localization of voids within the block

Abstract

The present paper discusses a Non Destructive Evaluation (NDE) technique involving Compton back-scattering. Two 15 cm x 15 cm x 15 cm cubical concrete blocks were scanned for detection of voids. The setup used a PC controlled gamma scattering scanning system. A 137Cs radioactive source of strength 153.92 GBq with lead shielding and a collimated and shielded 50% efficiency coaxial HPGe detector providing high resolution energy dispersive analysis of the scattered spectrum, were mounted on source and detector sub-assemblies respectively. In one of the concrete blocks air cavities were created by insertion of two hollow cylindrical plastic voids each of volume 71.6 cm3. Both the concrete blocks, one normal and another with air cavities were scanned by lateral and depth-wise motion in steps of 2.5 cm. The results show that the scattering method is highly sensitive to changes in electronic and physical densities of the volume element (VOXEL) under study. The voids have been detected with a statistical accuracy of better than 0.1% and their positions have been determined with good spatial resolution. A reconstruction algorithm is developed for characterization of the block with voids. This algorithm can be generally applied to such back-scattering experiments in order to determine anomalies in materials.