Transport measurement with a horizontal and a vertical pipe microphone in a mountain stream: taking account of particle saltation

The pipe microphone has been shown to be an effective means for monitoring bedload transport in mountain streams. It is commonly installed perpendicular to the flow direction on a stable river bed, such as that of a check dam. Acoustic pulses caused by bedload collisions with the pipe are detected b...

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Bibliographic Details
Published in:Earth surface processes and landforms 2018-04, Vol.43 (5), p.1118-1132
Main Authors: Tsutsumi, Daizo, Fujita, Masaharu, Nonaka, Michinobu
Format: Article
Language:English
Subjects:
Bed load
Bed-load discharge
bedload monitoring
Check dams
Discharge
Environmental monitoring
Hodaka sedimentation observatory
Microphones
Monitoring
Mountain streams
pipe microphone
Pipes
Repair & maintenance
Riverbeds
Rivers
Saltation
Sediment transport
Streams
Transport
vertical microphone
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Summary:The pipe microphone has been shown to be an effective means for monitoring bedload transport in mountain streams. It is commonly installed perpendicular to the flow direction on a stable river bed, such as that of a check dam. Acoustic pulses caused by bedload collisions with the pipe are detected by a microphone. However, bedload particles saltating over the pipe remain undetected. To overcome this disadvantage, we installed a horizontal as well as a vertical pipe microphone in the Ashi‐arai‐dani supercritical channel located in the Hodaka mountain range, Japan. The vertical pipe was installed on the wall of the channel and the horizontal pipe was installed on the channel bed. The acoustic response of the horizontal pipe is expected to be larger than that of the vertical pipe, because the bedload concentration decreases with increasing height above the bed. However, at high amplifications, the peak pulse value from the vertical pipe is higher than that from the horizontal pipe. We explain this observation as follows: under high bedload discharge conditions, the pulses of the horizontal pipe are saturated but those of the vertical pipe are not. We proposed a ratio (Rhv) between the pulses detected by these sensors, and applied this ratio for calibrating the contemporaneous pulses detected by a microphone located immediately upstream of a bedload slot sampler. Indeed the Rhv‐corrected pulses correlated well with the bedload discharge calculated from the sampler, supporting our explanation. We conclude that bedload monitoring using concomitant vertical and horizontal pipe microphones can be used to calibrate centrally located pipe microphones when the bedload concentration is approximately homogeneous laterally across the width of the channel cross‐section, and thereby represent bedload discharges more accurately than with only a single pipe microphone. Copyright © 2017 John Wiley & Sons, Ltd. New bedload monitoring using concomitant vertical and horizontal pipe microphones is conducted. A ratio (Rhv) between the numbers of pulses detected by these sensors is proposed. Pulses counted by a centrally located pipe microphone are corrected by the ratio, and correlated well with the bedload discharge calculated from the sampler.
ISSN:0197-9337
1096-9837
DOI:10.1002/esp.4297