Laboratory study and measurement of stiffness and compaction of unsaturated clay soil by using the innovative rebound hammer

Authors

  • Behrouz Halimi Department Of Engineering , Arak Branch, Islamic Azad University, Arak, Iran
  • Hamidreza Saba Department Of Civil Engineering, Tafresh University, Tafresh , Iran
  • Saeid Jafari MehrAbadi Department Of Engineering , Arak Branch, Islamic Azad University, Arak, Iran
  • Saeid Saeidi Jam Department Of Civil Engineering , Hamedan Branch, Islamic Azad University, Hamedan, Iran

DOI:

https://doi.org/10.5377/nexo.v34i02.11557

Keywords:

rebound Hammer, compressive behavior, soil stiffness, spring-damper model, unsaturated clay

Abstract

Defining soil behavioral parameters, which eventually results in predicting every short-term and long-term soil behavior, has continually been one of the interests of soil mechanics and has been of exceptional value. To this end, in this study, a novel method has been reviewed to determine the compressive behavior of fine-grained soils in the laboratory and the field, without sampling by the patented electronic device. In the lab, homogeneous materials of the intended soil underwent the compaction test, mechanical and physical tests, direct shear test, and impacts of the innovative rebound hammer in the horizontal and vertical directions in the test-box. The impact shear waves produce resistance and voltage output by force and dislocation sensors with high-sensitivity proportional to the pressure based on the soil surface stiffness. The obtained voltages are then converted to digital by an analog-to-digital converter and a microcontroller. Next, a number is shown on display by the "CodeVision" program. Then, by solving a quasi-dynamic equation (Viscoelastic spring-damper model) by MATLAB software and with the aid of laboratory-field results and correlation equations, a fitting connection between all effective mechanical soil parameters has been estimated to an acceptable extent. The effective mechanical parameters of the soil include the compaction percentage, specific gravity, and frequency of the system in the damped and non-damped states, the energy imposed on the soil, and the plastic stage strain in the range of less than 15% humidity. The results determine that increased hammering numbers are directly related to increased soil compaction and stiffness. In more detail, the reading of hammer numbers less than 2 corresponds to compaction of less than 75%, while the reading of hammer numbers greater than 3 in the vertical and 2.94 in the horizontal directions on clay surfaces designates compaction of 90%.

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Published

2021-06-07

How to Cite

Halimi, B., Saba, H., Jafari MehrAbadi, S., & Saeidi Jam, S. (2021). Laboratory study and measurement of stiffness and compaction of unsaturated clay soil by using the innovative rebound hammer. Nexo Scientific Journal, 34(02), 710–732. https://doi.org/10.5377/nexo.v34i02.11557

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