This paper presents a comprehensive theoretical design framework and efficiency analysis for a small-scale hydropower turbine intended to support sustainable, decentralized, and low-impact energy generation. As global energy demand continues to rise and the effects of climate change intensify, the need for resilient renewable power systems has become increasingly urgent. Small hydropower (SHP) technologies offer a practical solution for rural, remote, and off-grid regions by providing reliable, low-cost electricity without the ecological disruption commonly associated with large dam infrastructure. In response to this need, the present study develops and evaluates a simplified impulse-turbine model-representative of Pelton- and Turgo-type micro-hydro systems using fundamental fluid mechanics principles, Bernoulli-based jet velocity predictions, and classical momentum-transfer turbine equations.

The analysis investigates the relationship between hydraulic head, flow rate, jet formation, and mechanical power output while accounting for real-world loss mechanisms introduced by penstock friction, nozzle inefficiencies, turbulence, flow separation, jet dispersion, mechanical drag, and misalignment. By integrating analytical modeling with insights from the contemporary computational fluid dynamics (CFD) literature, this study identifies how nozzle geometry, jet coherence, bucket shape, and runner design strongly influence momentum transfer and overall turbine efficiency. Loss mechanisms are categorized into penstock, nozzle, runner, and mechanical components, each quantified with established efficiency factors and combined multiplicatively to provide a realistic system-level performance estimate.

Results demonstrate that while power output increases with hydraulic head and flow rate, diminishing returns emerge at high operating extremes due to intensifying turbulence and mechanical losses. The analysis confirms that peak efficiency occurs only within a narrow bucket-to-jet speed-ratio range, consistent with established impulse-turbine theory. This study additionally highlights practical considerations essential for real-world applications, including material selection, erosion resistance, sediment effects, manufacturability, site-specific turbine adaptation, and the influence of seasonal flow variability on long-term system reliability. Overall, the findings provide a detailed foundation for optimizing micro-hydropower systems intended for sustainable, decentralized energy deployment.