An Analytic Thermodynamic Model for Hydraulic Resistances Based on CFD Flow Parameters

Grabe, Christian von; Riedel, Christian; Stammen, Christian; Murrenhoff, Hubertus

doi:10.1080/14399776.2013.10781072

Cited by 5 publications

(2 citation statements)

References 8 publications

(9 reference statements)

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“…Valve performance affects the behavior of hydraulic systems significantly; the typical parameter used to characterize the flow through the valve restriction is the discharge coefficient. It is experimentally evaluated in the valve relevant operating range, and it allows to model the flow rate through the valve, under steady conditions [1][2][3].…”

Section: Introductionmentioning

confidence: 99%

A Novel Approach for Hydraulic Valve Experimental Assessment Under Cavitating Condition

Cavallo

Chiavola

Frattini

et al. 2022

TJFP

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The article presents a novel approach for the experimental characterization of hydraulic valves. The proposed methodology allows to capture the key layout of the valve, to study its characteristic flow rate and to visualize the flow that passes through it. In the wake of the experimental technique found in the literature, the novel approach introduces the use of an original test valve, briefly called “prismatic”. It represents an effective alternative to the so-called “Half-Cut Model” (HCM) proposed by Oshima and Ichikawa. The new test valve simplifies the experimental set-up and allows to visualize the whole internal flow field, providing full insight in both the inception and the spatial development of the cavitation. Moving from the HCM, the key features of the prismatic valve are preliminarily investigated and assessed by modelling, trough 3-D CFD simulations within OpenFOAM environment. Once the layout of prismatic valve is defined, the experimental assessment phase is carried out, highlighting its capability in research and development activities.

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Section: Introductionmentioning

confidence: 99%

A Novel Approach for Hydraulic Valve Experimental Assessment Under Cavitating Condition

Cavallo

Chiavola

Frattini

et al. 2022

TJFP

View full text Add to dashboard Cite

show abstract

“…Additionally, with the development of computer technology and the rapid improvement of hard software capability, commercial Computational Fluid Dynamics (CFD) software enables researchers to devote more energy to considering the physical nature of computational flow problems, as well as the rationality of boundary (initial value) conditions and calculation results (Akbarian et al, 2018;Chau & Jiang, 2002, 2004Faizollahzadeh Ardabili et al, 2018;Gao, Zhang, Liu, Sun, & Tian, 2018;Mou, He, Zhao, & Chau, 2017;Peng, Gui, & Fan, 2018;Wu & Chau, 2006;Zhang, Ma, Hong, Yang, & Fang, 2017). CFD analysis has been widely applied for orifice flow predictions in recent years (Araoye, Badr, & Ahmed, 2017;Di Rito, 2007;Reader-Harris, Barton, & Hodges, 2012;Roul & Dash, 2012;Schrank & Murrenhoff, 2013;Shah, Joshi, Kalsi, Prasad, & Shukla, 2012;Singh & John Tharakan, 2015;von Grabe, Riedel, Stammen, & Murrenhoff, 2013;Yau, Kua, & Balvinder, 2017).…”

Section: Introductionmentioning

confidence: 99%

Investigation of flow through the two-stage orifice

Gao

2019

Engineering Applications of Computational Fluid Mechanics

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In the field of engineering, understanding the flow characteristics of an orifice is key to accurately controlling pressure or flow; however, the transitional flow characteristics of the two-stage orifice has not been studied. The value of the discharge coefficient parameterizing the two-stage orifice flow equation is primarily based on that of the single classic orifice; however, this assumption leads to significant errors, because of the different numbers in the sudden contraction structure. Through theoretical derivation, the flow equations difference between the two-stage orifice and single classic orifice was compared and analyzed. Combing theoretical analysis, Computational Fluid Dynamics (CFD) simulation and experimental measurement, the transitional flow characteristics of the twostage orifice were investigated using mineral oil. The comparison results of the three parts are essentially consistent. In this paper, the discharge coefficient and the pressure drop over the twostage orifice were primarily focused on Reynolds numbers between 900 and 1700. In comparison with the single orifice, the results show that under the same dimensions (d = 3 mm), the discharge coefficient of the two-stage orifice is greater, and the transitional flow state of the two-stage orifice is different from that of the single orifice. Additionally, the pressure drop of the two-stage orifice is less than that of the single orifice under the same volume flow rate. The prestage cylindrical hole slows the changing trend of the flow field parameters, and the second-stage orifice with smaller diameter is mainly responsible for the pressure loss. The current research provides important support for accurate pressure and flow control of the two-stage orifice, and the role of the prestage cylindrical hole can also be a good reference in the structure design of micro-orifices.

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Modeling of Cavitation-Induced Air Release Phenomena in Micro-Orifice Flows

Freudigmann

Dörr

Iben³

et al. 2017

Journal of Fluids Engineering

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Impurities like air bubbles in hydraulic liquids can significantly affect the performance and reliability of hydraulic systems. The aim of this study was to develop a model suited for hydraulic system simulation to determine the rate of degassing of dissolved air in a micro-orifice flow at cavitating conditions. An existing model for the flow through a micro-orifice was extended to account for the generation of vapor which is suggested to play the key-role for the degassing mechanism. In comparison with measurements, the results of the modeling approach imply that diffusive mass transfer of dissolved air into generated vapor cavities is the dominating mechanism for the observed air release phenomena.

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An Analytic Thermodynamic Model for Hydraulic Resistances Based on CFD Flow Parameters

Cited by 5 publications

References 8 publications

A Novel Approach for Hydraulic Valve Experimental Assessment Under Cavitating Condition

A Novel Approach for Hydraulic Valve Experimental Assessment Under Cavitating Condition

Investigation of flow through the two-stage orifice

Modeling of Cavitation-Induced Air Release Phenomena in Micro-Orifice Flows

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