On the Volumetric Loss Caused by Incomplete Filling with Undissolved Gas in Positive Displacement Pumps: Lumped Parameter Modeling, CFD Comparisons, and Experimental Validations
DOI:
https://doi.org/10.13052/ijfp1439-9776.2622Keywords:
Incomplete filling of positive displacement pump, undissolved gas measurement, lumped parameter pump model, 1st-order air-release cavitation, equivalent total air, CFD study of pipe transient air releaseeAbstract
The analysis of the incomplete filling behavior of positive displacement machines requires considerations of the air content within the fluid and its dependency with the suction conditions, which are often associated with high uncertainties. This study contributes to this topic by experimentally studying the incomplete filling behavior of a positive displacement pump and presenting a hybrid modeling method for predicting it. The experimental study involved an original pump testing setup able to measure the gas volume fraction by interpreting the sound wave transmission behavior. Experimental results show that under same sub-atmospheric pump inlet pressure, low-speed operation can enhance the incomplete filling. This behavior is found related to the transient air release process in the line connecting the upstream pressure restriction location (which regulates the sub-atmosphere line pressure) to the pump, which is an effect often neglected in similar analyses on positive displacement machines that neglects the effect of the suction line. Based on the experimental study, a hybrid modeling method for predicting the volumetric losses caused by incomplete filling is proposed, where (i) the amount of undissolved gas in the hydraulic circuit upstream the pump is evaluated by a 1st-order gas release formulation, and (ii) the pump volumetric loss due to incomplete filling is simulated with a lumped volume-based pump model (LP pump model) with an gas-equilibrium fluid model with an equivalent total gas determined from step (i). The 1st-order gas release prediction approach was validated by CFD results of sub-atmospheric pipe flows, for a range of gas-release 1st-order time constants. Using a time constant of 8 s and total air of 6 %, the 1st-order formulation was also validated with experiments. The volumetric loss predicted by the LP pump model were found to agree with the measured pump volumetric efficiency at different operating conditions. The proposed hybrid approach presents a useful simulation tool for studying the incomplete filling of positive displacement pumps with sub-atmospheric inlet pressures, with consideration concerning the layout of the suction circuit.
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