Variable Seepage Meter Efficiency in High-Permeability Settings
Abstract
:1. Introduction
- where
- ES is the multiplier to compensate for seepage meter undermeasurement (unitless) and is the inverse of seepage meter efficiency;
- ∆V is the change in volume of water contained in the seepage bag (m3);
- ∆t is the duration of seepage bag connection to the seepage cylinder (commonly minute or day);
- A is the inside area of the seepage cylinder, equal to the area of the sediment bed being measured (m2).
1.1. Sources of Inefficiency
- where
- ΔP is pressure drop over the length of the tubing (kg/m/s2);
- µ is dynamic viscosity determined at the water temperature (kg/m/s);
- L is the tubing length (m);
- Q is the volumetric seepage rate (m3/s);
- R is the radius of the tubing (m).
1.2. Reported Seepage Meter Efficiency
1.3. Purpose and Scope
2. Materials and Methods
2.1. Seepage Bag Efficiency Tests
2.2. Simulation of K Versus Seepage Meter Efficiency
3. Results
3.1. Efficiency Results from Seepage Calibration Tank Measurements
3.1.1. Bag Efficiency Related to Bag Fullness
3.1.2. Efficiency Related to Seepage Velocity
3.1.3. Efficiency Related to Bag Connection Duration
3.1.4. Efficiency Related to Upward vs. Downward Seepage
3.1.5. Inertial Effects of Shutting Down Seepage Prior to a Measurement
3.1.6. Seepage Cylinder Installation Depth
3.2. Influence of Hydraulic Conductivity on Meter Efficiency
4. Discussion
4.1. Recommended Practices to Maximize Efficiency and Consistency
- Operate seepage bags in the mid-range of their capacity;
- Use shorter rather than longer bag connection times;
- Maintain continuous flow through the meter prior, during, and after bag attachment;
- Use thin-wall, pliable seepage bags and avoid using high-capacity seepage bags;
- Press the seepage cylinder more deeply into the sediment where possible;
- Avoid routing water through sharp bends in the seepage-measurement device;
- Use a meter that does not require inflation or deflation of a seepage bag.
4.1.1. Operate Seepage Bags from about 1/5 to 2/3 Full
4.1.2. Use Shorter rather than Longer Bag Connection Times in Highly Permeable Sediments
4.1.3. Maintain Continuous Flow through the Seepage Cylinder during Bag Attachment and Removal
4.1.4. Use Thin-Wall Seepage Bags and Avoid Using a High-Capacity Seepage Bag
4.1.5. Install the Seepage Cylinder Deeper into the Bed Sediment
4.1.6. Avoid Sharp Bends that Can Create Inertial Effects
4.1.7. Replace the Bag with another Flow-Measurement Device
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Seepage Rate, cm/d | Bag-Averaged Efficiency, % | Average Efficiency, % | Average Efficiency for First 3 Min, % |
---|---|---|---|
2.1 | 18 | 18 | 81 |
4.7 | 51 | 51 | 59 |
6.8 | 68, 73, 62, 51 | 64 | 79 |
7.9 | 67, 49, 46 | 53 | 74 |
13.5 | 78, 79, 75 | 77 | 80 |
38.7 | 88, 86, 87 | 87 | 87 |
Percent Bag Fullness | Continuous Flow, mL/min | Stopped Flow, mL/min | Stopped ÷ Continuous |
---|---|---|---|
75–100 | −15.02 | −11.93 | 79% |
25–75 | −12.00 | −7.31 | 61% |
25–75 | −12.67 | −7.54 | 60% |
25–75 | −12.00 | −4.09 | 34% |
0–25 | −5.09 | −3.11 | 61% |
Average | −11.36 | −6.80 | 59% |
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Rosenberry, D.O.; Nieto López, J.M.; Webb, R.M.T.; Müller, S. Variable Seepage Meter Efficiency in High-Permeability Settings. Water 2020, 12, 3267. https://doi.org/10.3390/w12113267
Rosenberry DO, Nieto López JM, Webb RMT, Müller S. Variable Seepage Meter Efficiency in High-Permeability Settings. Water. 2020; 12(11):3267. https://doi.org/10.3390/w12113267
Chicago/Turabian StyleRosenberry, Donald O., José Manuel Nieto López, Richard M. T. Webb, and Sascha Müller. 2020. "Variable Seepage Meter Efficiency in High-Permeability Settings" Water 12, no. 11: 3267. https://doi.org/10.3390/w12113267
APA StyleRosenberry, D. O., Nieto López, J. M., Webb, R. M. T., & Müller, S. (2020). Variable Seepage Meter Efficiency in High-Permeability Settings. Water, 12(11), 3267. https://doi.org/10.3390/w12113267