Effect of the Gas to Wall Temperature Ratio on the Bypass Transition

Rubini, Riccardo; Maffulli, Roberto; Arts, Tony

doi:10.1115/gt2018-76214

Cited by 4 publications

(2 citation statements)

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“…Their results are compared with the experimental work by Liepmann and Fila [40] who also highlighted the stabilizing effect of cooling on air flows. In contrast with the aforementioned findings referred to a natural transition, other studies [41][42][43] show that cooling promotes the bypass transition even if such behavior is opposite to what was expected from the small disturbance stability theory. These results nevertheless seem to be qualitatively in agreement with those observed experimentally by Back et al [44].…”

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confidence: 58%

Impact of Wall Temperature on Aerothermal Characteristics of an Array of Surface Microstructures

Campanaro

2022

Journal of Fluids Engineering

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The aero-thermal behaviour of surface microstructures is of wide relevance, especially given the development of additive manufacturing (AM). Of particular interest is the interaction between fluid flow and heat transfer. In the present work, two contrasting configurations, a flat plate boundary layer and an array of hemispheric micro-structures are examined at three wall-inflow temperature ratios (TR): cooled (T R=0.5), adiabatic (T R=1) and heated wall (T R=1.5). Due to a compensation between fluid viscosity and velocity gradient in the boundary layer, the heat transfer effects may appear deceptively small if judged using the common aerothermal parameters (Cf ,Nu). The authors find instead the local Reynolds number to be more usefully indicative of such aerothermal interaction. The scale-resolving LES simulations at a range of Reynolds numbers show that the cooled wall case is characterized by a markedly earlier transition which takes place at a much lower (by 50%) bulk flow Reynolds number compared to a near-adiabatic case. Furthermore, it is shown that the incompressible flow LES solutions fail to capture the early transition under the same cooling condition. Finally, a regrouping of the non-dimensional parameters (CD, Nu) with TR is proposed leading to more unified characterization for easier scaling of wall heat transfer effects in practical applications.

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confidence: 58%

Impact of Wall Temperature on Aerothermal Characteristics of an Array of Surface Microstructures

Campanaro

2022

Journal of Fluids Engineering

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“…Even when the above considerations are not an issue, URANS is limited by its inherent empirical nature; it is well known to struggle to capture the effects of buoyancy, stratification, rotation, streamline curvature, and transition. The latter is aggravated by a wall heat flux, which contributes to destabilising laminar boundary layers [22]. All of these are relevant for rotating cavity flows.…”

Section: Computational Investigationsmentioning

confidence: 99%

Some Observations on the Computational Sensitivity of Rotating Cavity Flows

Hickling

2021

Journal of Engineering for Gas Turbines and Power

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Across the open literature, there is no clear consensus on what the most suitable modelling fidelity is for rotating cavity flows. Although it is a widely held opinion that URANS approaches are unsuitable, many authors have succeeded in getting reasonable heat transfer results with them. There is also a lack of research into the validity of hybrid URANS/LES type approaches such as DES. This paper addresses these research challenges with a systematic investigation of a rotating cavity with axial throughflow at Grashof numbers of 3.03 × 109 and 3.03 × 1011. The disk near-wall layers remained laminar at both conditions, meaning that a turbulence model should not be active in these regions. The disk heat transfer was observed to affect the near-disk aerodynamics, which in turn affect the disk heat transfer: this feedback loop implies that conjugate heat transfer computations of rotating cavities may be worth investigating. On the shroud, additional eddy viscosity in URANS and DES was found to interfere with the formation of heat transfer enhancing streaks, whilst these were always captured by LES. DES exhibited a concerning behaviour at the higher Grashof number. Locally generated eddy viscosity from the shroud was injected into the bulk fluid by the radial inflow. This contaminated the entire cavity with non-physical modelled turbulence. As the radial inflow is a characteristic feature of rotating cavity flows, these results show that caution is necessary when applying hybrid URANS/LES approaches to this type of flow.

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Effects of coolant and wall temperature variations on impingement jet array thermal performance

Deng

Ligrani

et al. 2020

Numerical Heat Transfer, Part A: Applications

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Effect of the Gas to Wall Temperature Ratio on the Bypass Transition

Cited by 4 publications

References 0 publications

Impact of Wall Temperature on Aerothermal Characteristics of an Array of Surface Microstructures

Impact of Wall Temperature on Aerothermal Characteristics of an Array of Surface Microstructures

Some Observations on the Computational Sensitivity of Rotating Cavity Flows

Effects of coolant and wall temperature variations on impingement jet array thermal performance

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