Abstract
High-capacity tensiometers (HCTs) are sensors made to measure negative pore water pressure (suction) directly. In this paper, a new approach is proposed to expand the range and duration of suction measurements for a newly designed HCT. A new technique is employed to reduce significantly the roughness of the diaphragm’s surface on the water reservoir side in order to minimise the possibility of gas nuclei development and the subsequent early cavitation at the water–diaphragm interface. The procedures employed for the design, fabrication, saturation and calibration of the new tensiometers are explained in detail. Furthermore, the performance of the developed HCTs is examined based on a series of experiments carried out on a number of unsaturated clay specimens. An improvement in maximum sustainable suction in the range of 120–150% of their nominal capacity was obtained from different surface treatment methods. Moreover, the results show an improvement of up to 177% for the long-term stability of measurements, compared to the developed ordinary HCTs with untreated diaphragms.
Highlights
Geotechnical ResearchCavitation in high-capacity tensiometers: effect of water reservoir surface roughness
Difficulties in the measurement and control of soil suction in laboratory- and field-based experiments has led to the development of a number of techniques such as filter paper, psychrometer, thermal conductivity sensors, axis translation, pressure plate and tensiometers
Smoother and more water-attractive surfaces in the water reservoir can significantly reduce the number of entrapped gas bubbles and nucleation sites, increasing the cavitation threshold in High-capacity tensiometers (HCTs)
Summary
Cavitation in high-capacity tensiometers: effect of water reservoir surface roughness
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