Investigation and Control of the Blasting-Induced Ground Vibration under Cold Condition

This paper focuses on the investigation and control of the blasting-induced ground vibration under cold condition. The mechanical performance and wave propagation characteristics of the frozen rock mass are quite different from that of the conventional condition. Laboratory tests were implemented to...

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Bibliographic Details
Published in:Shock and vibration 2021, Vol.2021 (1)
Main Authors: Hu, Yingguo, Yang, Zhaowei, Yao, Erlei, Liu, Meishan, Rao, Yu
Format: Article
Language:English
Subjects:
Attenuation coefficients
Blasting
Cold
Earthquakes
Experiments
Freezing
Ground based control
Ground motion
Hydroelectric power stations
Laboratories
Laboratory tests
Longitudinal waves
Mechanical properties
Numerical analysis
Physical properties
Porosity
Propagation
Reconstruction
Rock masses
Seismic waves
Simulation methods
Stone
Velocity
Vibration monitoring
Water-power
Wave attenuation
Wave propagation
Wave velocity
Weight
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Summary:This paper focuses on the investigation and control of the blasting-induced ground vibration under cold condition. The mechanical performance and wave propagation characteristics of the frozen rock mass are quite different from that of the conventional condition. Laboratory tests were implemented to investigate the wave impedance of rock mass in the frozen, saturated, normal, and drying states. Results reveal the longitudinal wave velocity could be enlarged by 40 percent in the frozen state. Then long-term monitoring of blasting vibration was implemented based on the blasting excavation of the Fengman hydropower station reconstruction project in the north of China. Results demonstrate the PPV and frequency both attenuate much slower when the rock mass is frozen, and the obvious turning points of PPV could be found between different temperatures, where the change of the PPV relationship happens. At last, numerical simulation of the blasting seismic wave attenuation and the response in the protected structure was implemented. The equivalent freezing simulation method was proposed and verified with the site experiment data. Results demonstrate that the attenuation coefficient decreases obviously as the frozen depth of the rock mass increases. The dynamic degree response in structure is much stronger and the maximum charge weight per delay was limited more strictly under the frozen condition. A most adverse frozen depth was determined when the charge weight per delay gets the minimum value. With the above control approaches, a total of 676 blasting was completed in Fengman hydropower station reconstruction and no case of excessive measurement could be found.
ISSN:1070-9622
1875-9203
DOI:10.1155/2021/6660729