Abstract
This paper deals with the comparison of different methods which can be used for the prediction of the performance curves of pumps as turbines (PATs). The considered approaches are four, i.e., one physics-based simulation model (“white box” model), two “gray box” models, which integrate theory on turbomachines with specific data correlations, and one “black box” model. More in detail, the modeling approaches are: (1) a physics-based simulation model developed by the same authors, which includes the equations for estimating head, power, and efficiency and uses loss coefficients and specific parameters; (2) a model developed by Derakhshan and Nourbakhsh, which first predicts the best efficiency point of a PAT and then reconstructs their complete characteristic curves by means of two ad hoc equations; (3) the prediction model developed by Singh and Nestmann, which predicts the complete turbine characteristics based on pump shape and size; (4) an Evolutionary Polynomial Regression model, which represents a data-driven hybrid scheme which can be used for identifying the explicit mathematical relationship between PAT and pump curves. All approaches are applied to literature data, relying on both pump and PAT performance curves of head, power, and efficiency over the entire range of operation. The experimental data were provided by Derakhshan and Nourbakhsh for four different turbomachines, working in both pump and PAT mode with specific speed values in the range 1.53–5.82. This paper provides a quantitative assessment of the predictions made by means of the considered approaches and also analyzes consistency from a physical point of view. Advantages and drawbacks of each method are also analyzed and discussed.
Highlights
In many applications, e.g., in water distribution networks [1,2], waste hydraulic energy may be available for conversion into useful electric energy
In general, the values predicted by all the four models are in agreement with the field data trend and the predicted trend is all in all physically sound over the entire range of operation; head is reproduced well by all models, mainly at higher flow rates and mainly for pumps as turbines (PATs) #4
The considered methodologies were applied to the experimental data of four pumps/PATs, having a specific speed in the range 1.53–5.82
Summary
E.g., in water distribution networks [1,2], waste hydraulic energy may be available for conversion into useful electric energy. As highlighted in [3], Pumps As Turbines (PATs) couple well with low and variable power, by allowing acceptable energy production with low installation costs. Pumps can be used in turbine mode by reversing flow direction [4]. PATs can be aimed at energy saving and recovering in a water distribution network [6,7]. The paper [6] showed that (i) the system is viable in different scenarios and (ii) this strategy can replace a classic pumping system or supply the network in case the current hydraulic power is high. The work [7] compares
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