A CFD and experimental study on cavitation in positive displacement pumps: Benefits and drawbacks of the ‘full’ cavitation model

Iannetti, Aldo; Stickland, Matthew; Dempster, William

doi:10.1080/19942060.2015.1110535

Cited by 27 publications

(20 citation statements)

References 9 publications

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“…As can be seen in equation 12, the variation of the gas fraction over time is mainly affected by two factors: gas mass variation and mixture mass variation, which are represented by the two terms on the left of equation (12). According to the law of conservation of mass, the gas mass variation in the CV can be determined as follows:…”

Section: Gas Evolution and Transportationmentioning

confidence: 99%

“…11 Some of the aforementioned models were successfully implemented in commercial computational fluid dynamic solvers. [12][13][14][15] However, these approaches are often highly computationally expensive for simulation in complex fluid domains such as for axial piston machines. The lumped parameter of continuum modeling methods can be used for producing sufficiently accurate results, and a careful study of the overall features of hydraulic machines or components can reduce computational costs.…”

Section: Introductionmentioning

confidence: 99%

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First attempt to determine the critical inlet pressure for aircraft pumps with a numerical approach that considers vapor cavitation and air aeration

Dong

Wang

Chen³

2020

Proceedings of the Institution of Mechanical Engineers, Part G:

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Critical inlet pressure (CIP) is a key parameter for ensuring the long life and steady operation of aircraft piston pumps. In the past, this parameter was determined through experimental methods that had drawbacks such as a long duration and narrow application range. To identify an alternate approach that can be substituted for the traditional approach, a numerical model for determining the CIP that considers the dynamic effects of the transient period is proposed in this paper. First, a dynamic model of the pressure-controlled piston pump was established in the form of differential equations based on the lumped parameter method. Next, the fluid model for vapor cavitation and air aeration was derived using homogeneous mixture theory with consideration of the effects of compressibility of both liquid and gaseous phases. Simulation investigation highlighted how the shaft speed, inlet pressure, and transient time influence the fluid properties inside the piston chamber, and a method for determining the CIP both for steady and transient conditions is presented. Finally, tests were conducted on an aircraft piston pump in open-circuit applications for verifying the applicability of the proposed numerical model.

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Section: Gas Evolution and Transportationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

First attempt to determine the critical inlet pressure for aircraft pumps with a numerical approach that considers vapor cavitation and air aeration

Dong

Wang

Chen³

2020

Proceedings of the Institution of Mechanical Engineers, Part G:

View full text Add to dashboard Cite

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“…Based on CFD method, this paper mainly studies the movement characteristics of the suction valve and the distribution of the internal flow field during suction stroke. Due to the discharge valve is closed during this process, only the fluid in suction chamber, valve clearance and pump chamber needs to be considered and analyzed (Iannetti et al, 2016). Therefore, the geometric model established of fluid domain is shown in Fig.…”

Section: Geometric Modelmentioning

confidence: 99%

Analysis on the Performance Improvement of Reciprocating Pump with Variable Stiffness Valve using CFD

Zhu

Dong

2020

JAFM

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As a key component of reciprocating pump, the valve has a significant influence on its performance. However, it is difficult for the existing valve to simultaneously solve the problems such as fatigue, erosion and cavitation in engineering application. In this paper, a solution to these problems of using variable stiffness spring is proposed. And three new structures of the valve are designed. Furthermore, based on Computational Fluid Dynamics (CFD) method, a three-dimensional dynamic simulation model considering fluid-structure interaction in the suction stroke of reciprocating pump is established by using dynamic grid technique and User-Defined Functions (UDF). The performance of these new valves are compared with that of conventional valve respectively. The result shows that the new valves have significant influence on the motion characteristics of the valve disc, flow field distribution and cavitation. Besides, the simulation and experimental results of the maximum lift are compared, and it is found that they are basically in agreement. The new structures provide a new research direction for improving the performance of reciprocating pump. Simultaneously, the above simulation method can also provide guidance for valve design, structural optimization and service life improvement.

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“…In addition, CFD simulations have recently emerged as a powerful tool to analyze in detail the spatial characteristics of the flow patterns within volumetric flow pumps. The performance of plunger pumps as a function of the crank angle [14], the evaluation of its inlet stroke performance [15] and even cavitation inception [16,17] are some examples of the potentiality of computational modelling. The unsteady simulation of airoperated piston pumps [18] and the numerical analysis of axial piston pumps [19,20] are also significant contributions for the study of reciprocating pumps via CFD.…”

Section: Introductionmentioning

confidence: 99%

Numerical methodology for the CFD simulation of diaphragm volumetric pumps

Alberto

Manuel

Meana-Fernández

2019

International Journal of Mechanical Sciences

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This paper presents the unsteady numerical methodology for the CFD simulation of Air-Operated Diaphragm Pumps. The model reproduces the unsteady displacement of the diaphragm using dynamic mesh techniques and fully resolves the Fluid Structure Interaction (FSI) responsible for the motion of the check valves. The governing parameters have been modified with User Defined Functions (UDFs), using an implicit scheme for the grid motion that guarantees the stability and realizability of the twodimensional model adopted. The analysis of the instantaneous delivered flow rate, as a function of the discharged outlet pressure, has provided interesting and useful information for the future design of new prototypes. The comparison between numerical results and the experimental performance curves has confirmed the accuracy of the model and the correct mesh selection in the small gaps and passages of the pump internal geometry. The leakage flows, especially in the exhausting valve during the forward stroke, and the ball tapping responsible for instabilities and high-frequency noise during oscillations of the valves has been accurately simulated. At high-delivered pressures, it has been observed a characteristic ripple in the instantaneous flow rate during the deceleration of the diaphragm towards its top-dead-center, associated to a partial reopening of the exhausting valve. A closer look to the dynamics of the balls has revealed a strong coupling between inlet and outlet check valves. In addition, despite of the remarkable level of accuracy (less than 9% of deviation), the recirculating cells found in the flow fields inside the pump suggest the convenience of the development of a full-unsteady 3D model in the near future.

show abstract

A CFD and experimental study on cavitation in positive displacement pumps: Benefits and drawbacks of the ‘full’ cavitation model

Cited by 27 publications

References 9 publications

First attempt to determine the critical inlet pressure for aircraft pumps with a numerical approach that considers vapor cavitation and air aeration

First attempt to determine the critical inlet pressure for aircraft pumps with a numerical approach that considers vapor cavitation and air aeration

Analysis on the Performance Improvement of Reciprocating Pump with Variable Stiffness Valve using CFD

Numerical methodology for the CFD simulation of diaphragm volumetric pumps

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