Agriculture and food sciences
RESEARCH ARTICLE   (Open Access)

Development and Evaluation of a Laboratory-Scale Hydrological Apparatus for Simulating Soil Erosion and Groundwater Processes

Fayaz Ahmad 1, Zainab Asad 1, Muhammad Haris 1, Huda Shafqat 1, Taj Ali Khan 1*

+ Author Affiliations

Applied Agriculture Sciences 2(1) 1-9 https://doi.org/10.25163/agriculture.2142301

Submitted: 05 February 2024  Revised: 15 April 2024  Published: 19 April 2024 

Abstract

Background: The effective management of water infiltration, runoff, and soil degradation remains a critical challenge in water resource planning and environmental management. With increasing global water management concerns, tools such as rainfall simulators and erosion and sediment control (ESC) measures have become essential in studying hydrological processes. These tools aid in understanding the impact of natural phenomena and human activities on water systems, soil erosion, and sediment transport. Methods: This study utilized a custom-built hydrological apparatus to simulate and monitor rainfall, runoff, and groundwater processes under controlled laboratory conditions. The apparatus featured adjustable components such as a sand tank, rainfall simulation system, and supporting frame to replicate varied hydrological scenarios. Experiments focused on surface water flow, groundwater abstraction, and soil erosion by simulating real-world conditions like rainfall intensity, soil composition, and slope variations. Data on water infiltration, erosion, and sediment transport were collected for analysis. Results: The apparatus successfully replicated diverse hydrological conditions, providing key insights into soil erosion, water infiltration, and runoff patterns. It demonstrated the effects of slope and soil composition on water retention, with clay soils showing the highest water retention (7.28 L/min) and sandy soils exhibiting rapid drainage (0.16 L/min). Simulated rainfall enabled the creation of storm hydrographs and detailed monitoring of overland flow and erosion. Groundwater experiments, using Darcy’s law, revealed how varying conditions affected subsurface flow rates and water table fluctuations. Conclusion: The study demonstrated that controlled laboratory simulations can provide high-quality data on hydrological processes, complementing field studies and enhancing the understanding of water management systems.

Keywords: Hydrological Apparatus, Soil Erosion Simulation, Groundwater Flow, Rainfall Simulation, Water Management

References

AL-Chlaibawi, S. H., & Gzar, H. A. (2020, July). The flow and transport parameter estimation of groundwater in a laboratory-scale sand tank aquifer. IOP Conference Series: Materials Science and Engineering, 888(1), 012067. IOP Publishing.

Amadu, M., & Miadonye, A. (2019). A laboratory scale drawdown testing for the determination of a model sand pack aquifer hydraulic parameters. Journal of Hydrogeology and Hydrological Engineering, 8(1).

Benito Rueda, E., Gomez-Ulla, A., & Diaz-Fierros Viqueira, F. (1986). Descripción de...

Blanquies, J., Scharff, M., & Hallock, B. (2003). The design and construction of a rainfall simulator.

Cullum, R. F. (1997). Electronic controls for rainfall simulators. Transactions of the ASAE, 40(3), 643-648. https://doi.org/10.13031/2013.21323

Eigel, J. D., & Moore, I. D. (1983). A simplified technique for measuring raindrop size and distribution. Transactions of the ASABE, 26(4), 1079-1084.

Ekern, P. C. (1950). Raindrop impact as the force initiating soil erosion. University of Wisconsin.

Elbasit, M. A. M. A., Ojha, C. S. P., Yasuda, Z. A. H., Salmi, A., & Ahmed, F. (2015). Rain microstructure and erosivity relationships under pressurized rainfall simulator. Journal of Hydrologic Engineering, 20(6), C6015001. https://doi.org/10.1061/(ASCE)HE.1943-5584.0001053

EPEMA, G. F., & Riezebos, H. T. b. (1983). Fall velocity of water drops at different heights as a factor influencing erosivity of simulated rain. In J. de Ploey (Ed.), Rainfall simulation, runoff and soil erosion (CATENA Supplement 4, pp. 1-17).

Foltz, R. B., & Dooley, J. H. (2003). Comparison of erosion reduction between wood strands and agricultural straw. Transactions of the ASABE, 46(5), 1389-1396.

Hanif, M. H., Adnan, M., Shah, S. A. R., Khan, N. M., Nadeem, M., Javed, J., & Waseem, M. (2019). Rainfall runoff analysis and sustainable soil bed optimization engineering process: Application of an advanced decision-making technique. Symmetry, 11(10), 1224. https://doi.org/10.3390/sym11101224

Hirschi, M. C., Mitchell, J. K., Feezor, D. R., & Lesikar, B. J. (1990). Microcomputer controlled laboratory rainfall simulator. Transactions of the ASAE, 33(6).

Horne, M. (2017). Design and construction of a rainfall simulator for large-scale testing of erosion control practices and products.

International Organization for Standardization. (1980). ISO 1438/1-1980(E). Water flow measurement in open channels using weirs and venturi flumes - Part 1: Thin plate weirs. Available from Global Engineering Documents at http://global.ihs.com

Laws, J. O. (1941). Measurements of the fall velocity of water drops and raindrops. Transactions of the American Geophysical Union, 22, 709-721.

Laws, J. O., & Parsons, D. A. (1943). The relation of raindrop-size to intensity. Transactions of the American Geophysical Union, 24, 452-460.

Meyer, L. D. (1965). Symposium on simulation of rainfall for soil erosion research. Transactions of the ASAE, 8, 63-65.

Miller, W. P. (1987). A solenoid-operated, variable intensity rainfall simulator. Soil Science Society of America Journal, 51(3), 832-834.

Mutchler, C. K., & Hermsmeier, L. F. (1965). A review of rainfall simulators. Transactions of the ASABE, 8(1), 67-68.

Navas, A., Alberto, F., Machín, J., & Galán, A. (1990). Design and operation of a rainfall simulator for field studies of runoff and soil erosion. Soil Technology, 3(4), 385-397.

Paige, G. B., Stone, J. J., Smith, J. R., & Kennedy, J. R. (2003). The Walnut Gulch rainfall simulator: A computer-controlled variable intensity rainfall simulator. Transactions of the ASAE, 20(1).

Shoemaker, A. L., Zech, W. C., & Clement, T. P. (2012). Laboratory-scale evaluation of anionic polyacrylamide as an erosion and sediment control measure on steep-sloped construction sites. Transactions of the ASABE, 55(3), 809-820.

Zokaib, S., & Naser, G. H. (2012). A study on rainfall, runoff, and soil loss relations at different land uses: A case in Hilkot watershed in Pakistan. International Journal of Sediment Research, 27(3), 388-393.

PDF
Full Text
Export Citation

View Dimensions


View Plumx



View Altmetric



7
Save
0
Citation
275
View
5
Share