A practical first-order diagnostic framework for assessing wastewater biopond performance in infrastructure-limited rural systems
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Department of Engineering Sciences, Faculty of Natural and Agricultural Sciences, University of the Free State, PO Box 339, Bloemfontein 9300, South Africa
Autor do korespondencji
Aden Myburgh
Department of Engineering Sciences, Faculty of Natural and Agricultural Sciences, University of the Free State, PO Box 339, Bloemfontein 9300, South Africa
SŁOWA KLUCZOWE
DZIEDZINY
STRESZCZENIE
Waste stabilisation ponds (WSPs), also referred to as wastewater bio-ponds, are widely used for low-cost wastewater treatment, but their performance is often difficult to assess due to the coupled influence of biological activity, water quality, pond geometry, hydraulic behaviour, and site-specific operating conditions. This study proposes a practical first-order diagnostic framework for supporting the assessment of WSP systems, particularly where conventional monitoring infrastructure is limited. The framework combines a systems-level understanding of biological, chemical, and physical pond processes with targeted water quality monitoring, field profile measurements, and image-based surface-flow characterisation. Particular attention is given to flow behaviour, since it influences hydraulic residence time, spatial variability, and treatment efficiency. A homography-based image processing workflow is introduced to transform recorded surface motion into a metric reference frame, allowing surface velocity vectors to be estimated from tracked flow features and used as indicative hydraulic information. Because no independent reference-flow measurement was available, the image-derived velocities and discharge estimates are presented as preliminary and indicative first-order hydraulic information for interpreting flow behaviour and approximate discharge conditions, rather than as standalone or quantitatively validated flow measurements. The framework was demonstrated using one surface-flow case study and a single water-quality monitoring campaign at the Woodlands Hills three-pond WSP system, together with a second surface-flow case study at an agricultural runoff channel connected to the Moses River. The results provide time-specific diagnostic insight into hydraulic behaviour and treatment response, but do not constitute replicated, seasonal, or generally representative evidence of WSP performance. The proposed framework therefore provides a practical basis for assessing existing WSP systems, identifying likely performance limitations, and guiding future validation and optimisation work.