Destructive and Non-Destructive Testing and Evaluation Services

Half-cell potential (HCP) is a nondestructive test method used to investigate the thermodynamic corrosion tendency of embedded reinforcing steel. Potential readings measure the electrical activity of the corrosion process. Corrosion occurs simultaneously at steel’s anode and cathode areas when iron ions are released (at the anode areas) into the concrete to react and form deposits (at the cathode areas).

The HCP method involves making one electrical connection between reinforcing steel and the positive terminal of a high-impedance voltmeter and another between the negative terminal of the voltmeter and a reference electrode (RE). The RE comprises a copper electrode enclosed in a plastic housing surrounded by a saturated copper sulfate solution. The end of the cell is a porous disk through which the copper sulfate solution can make electrical contact with the concrete. The copper-copper sulfate (CSE) reference cell is the most widely used half-cell RE.

Impact-echo (IE) is an ultrasonic testing technique that entails introducing mechanical energy, in the form of a short pulse, into a structure and measuring its response. A transducer mounted on the impacted surface of the structure receives the reflected input waves or echoes as changes in the acoustic impedance in the materials are detected. Spectral analysis of the reflected compression wave is then performed to identify flaws and/or deterioration in the concrete or other material and to measure the thickness.

YA engineers have extensive experience using the IE test method. In the 1990s, they collaborated with the Federal Highway Administration (FHWA) Turner-Fairbank Highway Research Center in McLean, VA, in researching and developing the technology. YA has applied the IE test method to identify concrete-related problems in bridges, tunnels, slabs, foundations, pavements, masonry, and stone facades.

The Ultrasonic Shear Wave Tomography (USWT) test method, commercially known as the MIRA test unit, is a flaw detection system capable of generating 2D and 3D tomographic images of structural elements. The basic system consists of a console with 48 transducers aligned in 12 rows of modules containing four shear wave transducers each. The transducers are spring-loaded, dry-point contact (DPC) piezoelectric sensors with a center frequency of 50 kHz, configured as a single antenna array. Each transducer is built with a wear-resistant ceramic tip, which allows testing on rough surfaces without coupling gels.

Once the ultrasonic shear wave signal is emitted, the received signal is processed by the controlling console, and the 2D b-scan image is immediately displayed on the built-in screen. Then, a modified synthetic aperture focusing technique (SAFT-C) data processing analysis method is performed to generate 3D images of the test results.

Ultrasonic Pulse Velocity (UPV) is an ultrasonic testing technique that measures and assesses the transit time of reflected pulse stress waves through a material.

Detected changes in arrival time, amplitude, and the characteristics of the propagated mechanical waves can indicate changes in the internal makeup of the material. In concrete, internal conditions, such as the presence of honeycombing, internal cracking, and paste voids, affect the ability of a pulsed ultrasonic wave to propagate. While anomalies may slightly affect the transit time, and thus the corresponding computed pulse velocity, the effect on the signal strength and wave characteristics is more significant. Transient waves moving through anomalies will be attenuated, resulting in less total signal energy received through the member thickness.