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

Zachos, Pavlos K.; Grech, Nicholas; Charnley, B.; Pachidis, Vassilios; Singh, Riti

doi:10.1080/19942060.2011.11015350

Cited by 16 publications

(16 citation statements)

References 31 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The variables of i eq and δ eq herein can be gained by a typical correlation methodology developed by Lieblein [7] for conventional blades, which has been extensively employed by Banjac et al [9], McGlumphy [18], and Zachos et al [19]. The method can be expressed implicitly by Equations (10) and 11:…”

Section: Equivalent Values Of Incidence and Deviation Anglesmentioning

confidence: 99%

“…Therefore, it is necessary to correct the correlations with off-reference conditions so as to apply the model under practical compressor circumstances. Based on the basic correlations, the reference minimum-loss incidence and deviation angles can be modified with additional corrections from different factors, as shown in Equations (18) and (19):…”

Section: Corrections For Off-reference Conditionsmentioning

confidence: 99%

See 1 more Smart Citation

Development of a Preliminary Design Method for Subsonic Splittered Blades in Highly Loaded Axial-Flow Compressors

Liu

2017

Applied Sciences

View full text Add to dashboard Cite

This paper presents a model for predicting the reference minimum-loss incidence and deviation angles of a blade arrangement with splitter vanes, which is probably a solution for future ultra-highly loaded axial compressor designs. The motivation of the modeling is to guide the blading design in splittered compressor design processes where the additional splitter vanes must be specially considered. The development of the model is based on a blade performance database from systematic numerical simulations. Basic correlations of the model are firstly proposed, which consider dominant blade geometry parameters related to blade loading, including camber angle and solidity. Secondly, geometric and aerodynamic corrections about orientation parameter, blade maximum thickness, inlet Mach number, and three-dimensional (3D) effects are empirically incorporated into the basic correlations. Eventually, a subsonic 3D splittered rotor is designed using the correlations coupled with the corrections obtained from the validation of the model. The results indicate that the model is able to achieve a good agreement within an error band of ±1.0 • for the predictions of both reference minimum-loss incidence and deviation angles, and the rotor designed using the model accomplishes the desired work input and flow deflection.

show abstract

Section: Equivalent Values Of Incidence and Deviation Anglesmentioning

confidence: 99%

Section: Corrections For Off-reference Conditionsmentioning

confidence: 99%

Development of a Preliminary Design Method for Subsonic Splittered Blades in Highly Loaded Axial-Flow Compressors

Liu

2017

Applied Sciences

View full text Add to dashboard Cite

show abstract

“…Yet a detailed understanding of the flow features inside the critical components is essential for a reliable prediction of the overall performance, especially in severe off-design operating conditions. Available detailed experimental and numerical studies, conducted on a compressor cascade (Zachos et al, 2011) and on a contemporary high-bypass ratio turbofan in an altitude test cell (Prasad and Lord, 2010) indicate that, in windmilling operation, the fan stage operates under severe off-design (negative) angle-of-attack conditions, leading to the development of flow separation on both rotor and stator. These observations were confirmed by a previous experimental study on a small, geared turbofan, at ground level (García Rosa et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Experimental analysis of the unsteady, turbilent flow through the fan stage of a high-bypass turbofan in windmilling conditions

Rosa

Thacker

Dufour

2017

European Conference on Turbomachinery Fluid Dynamics and Hermodynamics

View full text Add to dashboard Cite

A detailed study of the unsteady airflow through the fan stage of a bypass turbofan is proposed. Experiments are conducted in the turbofan test facility of ISAE, specially suited to reproduce windmilling operation in an ambient ground setup. Hot-wire anemometry is used to obtain steady Mach number and flow angle profiles as well as to characterize the unsteady, turbulent flow, at different stations across the fan stage (fan inlet, outlet and rotor/stator interface). Phase averaging of unsteady signals and integral length scale estimations provide further evidence of the presence of a vortex shedding from the stator, as well as the fact that it is correlated to the rotor blade passing frequency. Self-similarity of mean Mach number, flow angle and turbulent intensity profiles is observed. Furthermore, turbulent scale profiles are found to scale well with blade passing period.

show abstract

“…However, the increasing fidelity and reliability of numerical solvers encourages their use for studying the spray phenomena under conditions that are otherwise difficult to reproduce within an experimental environment. Examples of successful application of CFD studies can be found in Zachos et al (2011), Manzar et al (2009) and Chalet et al (2010). In this paper, results from a number of atomizer CFD simulations that were run at sub-atmospheric pressures are presented.…”

Section: Introductionmentioning

confidence: 99%

Effect of Combustor Geometry on Performance of Airblast Atomizer Under Sub-Atmospheric Conditions

Grech

Mehdi

Zachos

et al. 2012

Engineering Applications of Computational Fluid Mechanics

Self Cite

View full text Add to dashboard Cite

ABSTRACT:One of the certification requirements that a jet engine has to fulfil is its altitude relight capability. Relighting an aero gas turbine engine at high altitudes is more challenging than at sea level conditions. The pressure, air velocity, and temperature within the combustor at such conditions are very low, hindering the fuel atomization and evaporation process. After ignition, combustion efficiency can be relatively low due to the poor fuel atomization quality, leading to slow shaft acceleration rates. Further studies in this field can help determine and predict the fuel spray characteristics, which limit the relight and pull-away capability of the engine at these sub-idle conditions. Reported in this paper is the CFD analysis of a typical airblast atomizer, simulated at different sub-idle operating conditions. Two sets of models were used; one with a simple liner-only combustor with co-flow air, and the other with a more detailed geometry, including wall cooling slots, primary and secondary dilution holes, and co-flow air. For the simpler model, three different inner and outer liner wall spacing were modelled to examine the effect of the chamber volume on the fuel spray behaviour. The CFD models were then run at a chamber pressure of 101, 41 and 31kPa, typical of sub-idle conditions. The effect of such conditions on the atomization quality of the fuel spray was analysed. The study carried out indicates how the chamber pressure, chamber volume and AFR (through amount of co-flow air introduced) significantly affect the resulting spray characteristics. A parametric analysis was performed to extract a correlation between the spray SMD (Sauter Mean Diameter) and fuel flow rate.

show abstract

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

Cited by 16 publications

References 31 publications

Development of a Preliminary Design Method for Subsonic Splittered Blades in Highly Loaded Axial-Flow Compressors

Development of a Preliminary Design Method for Subsonic Splittered Blades in Highly Loaded Axial-Flow Compressors

Experimental analysis of the unsteady, turbilent flow through the fan stage of a high-bypass turbofan in windmilling conditions

Effect of Combustor Geometry on Performance of Airblast Atomizer Under Sub-Atmospheric Conditions

Contact Info

Product

Resources

About