Numerical Characterization of Pressure Drop Across the Manifold of Turbine Casing Cooling System

Soghe, Riccardo Da; Andreini, Antonio

doi:10.1115/gt2012-68787

Cited by 3 publications

(6 citation statements)

References 6 publications

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“…Even developed referring to circular cross-section manifold geometries, DaSoghe and Andreini [18] proved the correlation reliability also in case of squared manifold geometries.…”

Section: Discharge Coefficient Correlationmentioning

confidence: 93%

“…By using the provided experimental data (see [17]) and validated CFD calculations, Andreini and DaSoghe [9] have developed an empirical correlation for the prediction of the impinging holes discharge coefficient: it expresses the C d of each hole as a function of the ratio between the hole and the manifold mass velocity and the local value of the pressure ratio. Recently, the authors have revised this correlation to make it sensible to the nozzle length-todiameter ratio [18]. The second test rig, aims to evaluate the heat transfer coefficient and the adiabatic effectiveness of a multijet impingement array (for which the undercowl flow is considered) which reproduces an active clearance control system of a commercial aircraft.…”

Section: Control Valvementioning

confidence: 99%

“…The correlation for the C d parameter considered in this study has been recently developed by DaSoghe and Andreini [9,18]. The expression is the result of an extensive CFD analysis: it expresses the C d of each impingement hole as a function of the ratio between the hole and the manifold mass velocity (MVR), the nozzle length-to-diameter ratio (t/d) and the local value of the β L ratio.…”

Section: Discharge Coefficient Correlationmentioning

confidence: 99%

“…For further details about the presented correlation and the related validation study, refer to Andreini and DaSoghe papers [9,18].…”

Section: Discharge Coefficient Correlationmentioning

confidence: 99%

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Aerothermal Analysis of a Turbine Casing Impingement Cooling System

Soghe

Facchini²,

Micio³

et al. 2012

International Journal of Rotating Machinery

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Heat transfer and pressure drop for a representative part of a turbine active cooling system were numerically investigated by means of an in-house code. This code has been developed in the framework of an internal research program and has been validated by experiments and CFD. The analysed system represents the classical open bird cage arrangement that consists of an air supply pipe with a control valve and the present system with a collector box and pipes, which distribute cooling air in circumferential direction of the casing. The cooling air leaves the ACC system through small holes at the bottom of the tubes. These tubes extend at about 180° around the casing and may involve a huge number of impinging holes; as a consequence, the impinging jets mass flow rate may vary considerably along the feeding manifold with a direct impact on the achievable heat transfer levels. This study focuses on the performance, in terms of heat transfer coefficient and pressure drop, of several impinging tube geometries. As a result of this analysis, several design solutions have been compared and discussed.

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“…Even developed referring to circular cross-section manifold geometries, DaSoghe and Andreini [18] proved the correlation reliability also in case of squared manifold geometries.…”

Section: Discharge Coefficient Correlationmentioning

confidence: 93%

Section: Control Valvementioning

confidence: 99%

Section: Discharge Coefficient Correlationmentioning

confidence: 99%

“…For further details about the presented correlation and the related validation study, refer to Andreini and DaSoghe papers [9,18].…”

Section: Discharge Coefficient Correlationmentioning

confidence: 99%

See 2 more Smart Citations

Aerothermal Analysis of a Turbine Casing Impingement Cooling System

Soghe

Facchini²,

Micio³

et al. 2012

International Journal of Rotating Machinery

Self Cite

View full text Add to dashboard Cite

show abstract

“…The maximum discrepancy in discharge coefficient between CFD and measurement is about 10% over a range of conditions. Also using the SST k ω − model, Da Soghe and Andreini [21] have studied discharge from a duct through multiple orifices aligned at right angles to the flow. CFD results from this study and earlier work by the same authors was used to produce a correlation for orifice discharge coefficient taking into account inlet cross flow, orifice pressure ratio, and orifice L/D ratio.…”

Section: Introductionmentioning

confidence: 99%

Velocity pick-up and discharge coefficient for round orifices with cross flow at inlet

Chew

Sun

2014

Proceedings of the Institution of Mechanical Engineers, Part C:

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A 3D Coupled Approach for the Thermal Design of Aero-Engine Combustor Liners

Mazzei

Andreini

Facchini

et al. 2016

Volume 5B: Heat Transfer

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The adoption of lean burn combustion to limit NOx emissions of modern aero-engines imposes a drastic reduction of air dedicated to cooling combustor dome and liners. In the latest years many aero-engine manufacturers are hence implementing effusion cooling, which provides uniform protection on the hot side of the liner and significant heat removal within the perforation. With an industrial perspective, the development of such components is usually carried out with different strategies depending on the level of accuracy required in the design phase involved (i.e preliminary or detailed). In the collaboration between GE Avio and University of Florence, the preliminary design of these devices is carried out with Therm1D, an in-house thermal flow-network solver based on the 1D correlative approach proposed by Lefebvre. This strategy, however, is not capable of taking into account the complexity of the three-dimensional nature of the flow field and the interaction between swirling flow and liner cooling, making necessary the use of Computational Fluid Dynamics (CFD) in the most advanced phases of the design process. Nevertheless, notwithstanding the increasing popularity of CFD, even a RANS simulation of a single sector of an annular combustor still presents a challenge, when the cooling system is taken into account. This issue becomes more critical in case of modern effusion cooled combustors, which may contain thousands of holes for each sector. With the aim of of increasing the fidelity of the prediction, keeping in mind the industrial needs for limited computational efforts, a new tool has been developed: Therm3D. This approach involves the CFD simulation of the combustor flametube by modelling effusion cooling with point mass sources, whereas the fluid dynamic prediction of the remaining part is fulfilled exploiting the equivalent flow-network solver implemented in Therm1D, which provides the estimation of flow split and cold side heat loads. The solution is coupled with two separate calculations aimed at solving flame radiation and heat conduction within the metal. This paper describes the main findings of the application of Therm3D to a lean annular combustor. The results obtained have been compared to experimental data and the above mentioned numerical tools employed during the design process.

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Numerical Characterization of Pressure Drop Across the Manifold of Turbine Casing Cooling System

Cited by 3 publications

References 6 publications

Aerothermal Analysis of a Turbine Casing Impingement Cooling System

Aerothermal Analysis of a Turbine Casing Impingement Cooling System

Velocity pick-up and discharge coefficient for round orifices with cross flow at inlet

A 3D Coupled Approach for the Thermal Design of Aero-Engine Combustor Liners

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