Numerical investigation of a low speed reacting flow behavior in a porous duct

Solidity in compressors is defined as the ratio of the aerodynamic chord over the peripheral distance between two adjacent blades, the pitch. This parameter is simply the inverse of the pitch-to-chord ratio generally used in turbines. Solidity must be selected at the earliest design phase, i.e. at the level of the meridional design and represents a crucial step in the whole design process. Most of the existing studies on this topic rely on low-speed compressor cascade correlations from Carter or Lieblein. The aim of this work is to update those correlations for state-of-the-art controlled diffusion blades, and extend their application to high Mach number flow regimes more typical of modern compressors. Another objective is also to improve the physical understanding of the solidity effect on compressor performance and stability. A numerical investigation has been performed using the commercial software FINE/Turbo. Two different blade profiles were selected and investigated in the compressible flow regime as an extension to the low-speed data on which the correlations are based. The first cascade uses a standard double circular arc profile, extensively referenced in the literature, while the second configuration uses a state-of-the-art CDB, representative of low pressure compressor stator mid-span profile. Both profiles have been designed with the same inlet and outlet metal angles and the same maximum thickness but the camber and thickness distributions, the stagger angle and the leading edge geometry of the CDB have been optimized. The determination of minimum loss, optimum incidence and deviation is addressed and compared with existing correlations for both configurations and various Mach numbers that have been selected in order to match typical booster stall and choke operating conditions. The emphasis is set on the minimum loss performance at mid-span. The impact of the solidity on the operating range and the stability of the cascade are also studied.

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Numerical Investigation of Gas‐Liquid Reacting Flow in a Jet‐Type Singlet Oxygen Generator

Chemical Engineering & Technology ◽

10.1002/ceat.201900156 ◽

2020 ◽

Vol 43 (9) ◽

pp. 1859-1865

Author(s):

Chao Xu ◽

Xi Chen ◽

Tingting Liu ◽

Ying Huai ◽

Guangwen Chen

Keyword(s):

Singlet Oxygen ◽

Numerical Investigation ◽

Reacting Flow ◽

Oxygen Generator ◽

Singlet Oxygen Generator

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Numerical Investigation of Blood Flow Behavior in Different Orders of Vascular System

CHEST Journal ◽

10.1378/chest.1388814 ◽

2012 ◽

Vol 142 (4) ◽

pp. 840A

Author(s):

Houman Tammadon ◽

Mehrdad Behnia ◽

Leonard Kritharides ◽

Masud Behnia

Keyword(s):

Blood Flow ◽

Numerical Investigation ◽

Vascular System ◽

Flow Behavior

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Influence of Circumferential Inflow Distortion on the Performance of a Low Speed, High Aspect Ratio Contra Rotating Axial Fan

Journal of Turbomachinery ◽

10.1115/1.4025953 ◽

2014 ◽

Vol 136 (7) ◽

Cited By ~ 15

Author(s):

Chetan Mistry ◽

A. M. Pradeep

Keyword(s):

Aspect Ratio ◽

High Aspect Ratio ◽

Rotational Speed ◽

Total Pressure ◽

Flow Behavior ◽

Axial Fan ◽

Low Speed ◽

Overall Performance ◽

Design Speed ◽

Inflow Conditions

The influence of circumferential inflow distorted on the performance and flow behavior of a high aspect ratio, low speed contra rotating fan is reported in this paper. The total pressure at the inlet is artificially distorted by means of 90 deg mesh sector with a porosity of 0.70. The performance of the contra rotating fan was studied under different speed combinations of the two rotors under clean and distorted inflow conditions. Detailed flow analyses were conducted under design and off-design conditions. In order to understand the effect of distortion and its extent, the distortion sector was rotated circumferentially at intervals of 15 deg to cover the entire annulus. Detailed measurements of the total pressure, velocity components, and flow angles were carried out at the inlet of the first rotor, between the two rotors, and at the exit of the second rotor. The study reveals a few interesting aspects on the effect of inflow distortion on the performance of a contra-rotating stage. For the design speed combination and lower rotational speed of rotor-2, a reduction in the overall operating range with a shift of the peak pressure point towards higher mass flow rate, was observed. It is observed that the effect of inflow distortion at the inlet of rotor-1 gets transferred in the direction of rotor-1 rotation and spreads across the entire annulus. The opposite sense of rotation of rotor-2 causes the distortion effect to get transferred in the direction of rotation of rotor-2 with an associated reduction in the total pressure near the hub. It is observed that a higher rotational speed of the second rotor has a beneficial effect on the overall performance due to the strong suction by generated higher rotational speed of rotor-2.

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Experimental and Numerical Investigation of Non-reacting Flow in Can Combustor for Microgas Turbine Engine

Lecture Notes in Mechanical Engineering - Innovative Design, Analysis and Development Practices in Aerospace and Automotive Engineering ◽

10.1007/978-981-15-6619-6_14 ◽

2020 ◽

pp. 131-137

Author(s):

V. Kirubakaran ◽

David S. Bhatt

Keyword(s):

Numerical Investigation ◽

Reacting Flow ◽

Turbine Engine

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The Effect of Boattail Angles on the Near-Wake Structure of Axisymmetric Afterbody Models at Low-Speed Condition

International Journal of Aerospace Engineering ◽

10.1155/2020/7580174 ◽

2020 ◽

Vol 2020 ◽

pp. 1-14

Author(s):

The Hung Tran

Keyword(s):

Strouhal Number ◽

Reynolds Shear Stress ◽

Flow Behavior ◽

Flow Characteristics ◽

Wake Flow ◽

Turbulent Intensity ◽

Near Wake ◽

Wake Structure ◽

Low Speed ◽

Speed Condition

The effect of a boattail angle on the structure of the wake of an axisymmetric model was investigated at low-speed condition. Four conical boattail models with angles of 0° (blunt-based body), 10°, 16°, and 22° were selected for this study. The Reynolds number based on the diameter of the model was around 1.97×104. Particle image velocimetry (PIV) was used to measure the velocity of the wake flow. The time-averaged flow characteristics including the length of recirculation of the afterbody, turbulent intensity, and Reynolds shear stress were analyzed and compared among those boattail models. The experimental results showed that the length of recirculation decreases with increasing boattail angle to 16°. At a boattail angle above 16°, the flow was fully separated near the shoulder and near-wake structure was highly changed. The turbulent intensity at a boattail angle of 22° showed a similar level to that in the case of the blunt-based body. Flow behavior on boattail surface should be accounted as an important parameter affecting the wake width and drag of the model. Power spectral density and proper orthogonal decomposition (POD) analyses showed that a Strouhal number of StD=0.2 dominated for the boattail model up to 16°. The fully separated flow was dominated by a Strouhal number of StD=0.03−0.06, which was firstly presented in this study.

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