A Fully Integrated Approach to Component Zooming Using Computational Fluid Dynamics

Pachidis, Vassilios; Pilidis, Pericles; Talhouarn, Fabien; Kalfas, A. I.; Templalexis, Ioannis

doi:10.1115/1.2135815

Cited by 38 publications

(18 citation statements)

References 4 publications

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“…5 The analysis of aerodynamic performance can be studied by several methods, including Conformal Mapping, 6 Thin Airfoil Theory, 7 Surface Panel Method, 8 or computational fluid dynamics (CFD) solutions. 9,10…”

Section: Introductionmentioning

confidence: 99%

Computational methods for investigation of surface curvature effects on airfoil boundary layer behavior

Shen

Avital

Rezaienia

et al. 2016

Journal of Algorithms & Computational Technology

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This article presents computational algorithms for the design, analysis, and optimization of airfoil aerodynamic performance. The prescribed surface curvature distribution blade design (CIRCLE) method is applied to a symmetrical airfoil NACA0012 and a non-symmetrical airfoil E387 to remove their surface curvature and slope-of-curvature discontinuities. Computational fluid dynamics analysis is used to investigate the effects of curvature distribution on aerodynamic performance of the original and modified airfoils. An inviscid-viscid interaction scheme is introduced to predict the positions of laminar separation bubbles. The results are compared with experimental data obtained from tests on the original airfoil geometry. The computed aerodynamic advantages of the modified airfoils are analyzed in different operating conditions. The leading edge singularity of NACA0012 is removed and it is shown that the surface curvature discontinuity affects aerodynamic performance near the stalling angle of attack. The discontinuous slope-of-curvature distribution of E387 results in a larger laminar separation bubble at lower angles of attack and lower Reynolds numbers. It also affects the inherent performance of the airfoil at higher Reynolds numbers. It is shown that at relatively high angles of attack, a continuous slope-of-curvature distribution reduces the skin friction by suppressing both laminar and turbulent separation, and by delaying laminar-turbulent transition. It is concluded that the surface curvature distribution has significant effects on the boundary layer behavior and consequently an improved curvature distribution will lead to higher aerodynamic efficiency.

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Section: Introductionmentioning

confidence: 99%

Computational methods for investigation of surface curvature effects on airfoil boundary layer behavior

Shen

Avital

Rezaienia

et al. 2016

Journal of Algorithms & Computational Technology

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“…Understanding the flow through blades at extremely high incidence enhances the component performance prediction methods but also the whole engine performance simulation for far off-design power settings such as thesub-idle relight transient maneuvers (windmill altitude and quick relights) or groundstarts. Additionally, the pressure loss modeling can be significantly enhanced with important benefits on the numerical tools where pressure loss models are employed (Novak, 1967;Pachidis et al, 2006). Finally, validation-calibration of CFD codes for predicting the extremely challenging areas of separated flows can be also carried out (Pachidis et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

“…Additionally, the pressure loss modeling can be significantly enhanced with important benefits on the numerical tools where pressure loss models are employed (Novak, 1967;Pachidis et al, 2006). Finally, validation-calibration of CFD codes for predicting the extremely challenging areas of separated flows can be also carried out (Pachidis et al, 2006). The increased computational power available nowadays throughout the research community has increased the application of high-fidelity numerical approaches on every kind of flow prediction, starting from pure aerodynamic phenomena occurring at inlets or compressors and extending them in combustion or turbine cooling research, employing multidisciplinary tools of chemical or heat transfer nature (Chaluvadi et al, 2003;Ramakrishna et al, 2009;Ummiti et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Experimental and Numerical Investigation of a Compressor Cascade at Highly Negative Incidence

Zachos

Grech

Charnley

et al. 2011

Engineering Applications of Computational Fluid Mechanics

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ABSTRACT:The performance prediction of axial flow compressors and turbines still relies on the stationary testing of blade cascades. Most of the blade testing studies are done for operating conditions close to the design point or in off-design areas not too far from it. However, blade-and consequently engine-performance remain unexplored at relatively far off-design conditions, such as windmilling or sub-idle. Such regimes are dominated by blade operation under extremely low mass flows and rotational speeds that imply highly negative values of incidence angle, thus totally separated flows on the pressure side of the blades. Those flow patterns are difficult to be measured and even more difficult to be numerically predicted as the current modelling capability of separated internal flows is of limited reliability. In this paper, the performance of a 3-dimensional linear compressor cascade at highly negative incidence angle is initially experimentally investigated. The main objective of the study is to derive the total pressure loss and outlet flow angle through the blades and use the data for the validation-calibration of a numerical solver enhancing its capability to predict highly separated flows. The development of the CFD model and the simulation strategy followedare also presented.The numerical results are compared against the derived test data demonstrating a good agreement. In addition, most trends of the properties of interest have been captured sufficiently, therefore the physical phenomena are considered to be well captured, allowing the numerical tool to be used for further studies on similar test cases.

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“…In this case the non-Newtonian properties of blood such as shear thinning and viscoelasticity are negligible. A density of 1050 kg/m 3 and viscosity of 0.0036 Pa.s were defined for the working fluid15. A mesh independence study was performed, in a similar fashion to a study conducted by Fraser et.…”

Section: Methodsmentioning

confidence: 99%

Optimization of Axial Pump Characteristic Dimensions and Induced Hemolysis for Mechanical Circulatory Support Devices

et al. 2018

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The application of axial pumps as ventricular assist devices (VADs) requires significant modifications to the size and characteristics of industrial pumps due to the difference in flow fields of industrial and medical pumps. Industrial pumps operate in the region of Reynolds number Re = 10, whereas axial blood pumps operate in Re < 10. The common pump design technique is to rely on the performance of previously designed pumps using the concept of fluid dynamic similarity. Such data are available for industrial pumps as specific speed-specific diameter (ns-ds) graphs. The difference between the flow fields of industrial and medical pumps makes the industrial ns-ds graphs unsuitable for medical pumps and consequently several clinically available axial blood pumps operate with low efficiencies. In this article, numerical and experimental techniques were used to design 62 axial pump impellers with different design characteristics suitable for VADs and mechanical circulatory support devices (MCSDs). The impellers were manufactured and experimentally tested in various operating conditions of flow, pressure, and rotational speed. The hemocompatibility of the impellers was numerically investigated by modeling shear stress and hemolysis. The highest efficiency of each pump impeller was plotted on an ns-ds diagram. The nondimensional results presented in this article enable preliminary design of efficient and hemocompatible axial flow pumps for VADs and MCSDs.

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A Fully Integrated Approach to Component Zooming Using Computational Fluid Dynamics

Cited by 38 publications

References 4 publications

Computational methods for investigation of surface curvature effects on airfoil boundary layer behavior

Computational methods for investigation of surface curvature effects on airfoil boundary layer behavior

Experimental and Numerical Investigation of a Compressor Cascade at Highly Negative Incidence

Optimization of Axial Pump Characteristic Dimensions and Induced Hemolysis for Mechanical Circulatory Support Devices

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