Andrew Sisler scite author profile

Andrew Sisler

5Publications

35Citation Statements Received

75Citation Statements Given

How they've been cited

118

How they cite others

Affiliations

National Energy Technology Laboratory, West Virginia University

Publications

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Flow Visualization of Multi-Hole Film-Cooling Flow under Varying Freestream Turbulence Levels

Repko¹,

Nix²,

Uysal³

et al. 2016

JFCMV

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A flat plate film cooling flow from a multi-exit hole configuration has been numerically simulated using both steady and unsteady Reynolds Averaged Navier Stokes (RANS and URANS) Computational Fluid Dynamics (CFD) formulations. This multi-exit hole concept, the Anti-Vortex Hole (AVH), has been developed and studied by previous research groups and shown to mitigate or counter the vorticity generated by conventional holes resulting in a more attached film cooling layer and higher film cooling effectiveness. The film cooling jets interaction with the free stream flow is a long studied area in gas turbine heat transfer. The present study numerically simulates the jet interaction with the multi-exit hole concept at a high blowing ratio (M = 2.0) and density ratio (DR = 2.0) in order to provide a more detailed, graphical explanation of the improvement in film cooling effectiveness. This paper presents a numerical study of the flow visualization of the interaction of film cooling jets with a subsonic crossflow. The contour plots of adiabatic cooling effectiveness were used to compare the multi-exit hole and conventional single hole configurations. The vortex structures in the flow were analyzed by URANS formulations and the effect of these vortices on the cooling effectiveness was investigated together with the coolant jet lift-off predictions. Quasi-Instantaneous Temperature Isosurface plots are used in the investigations of the effect of turbulence intensity on the cooling effectiveness and coolant jet coverage. The effect of varying turbulence intensity was investigated when analyzing the jets' interaction with the cross flow and the corresponding temperatures at the wall. The results show that as the turbulence intensity is increased, the cooling flow will stay more attached to the wall and have more pronounced lateral spreading far downstream of the cooling holes.

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Computationally Quantifying Loss Mechanisms in a Rotating Detonation Engine

Strakey

Ferguson

Sisler

et al. 2016

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Experimental Study of Rotating Detonation Combustor Performance under Preheat and Back Pressure Operation

Roy

Ferguson

Sidwell

et al. 2017

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Development of a Lab-Scale Experimental Testing Platform for Rotating Detonation Engine Inlets

Bedick

Sisler

Ferguson

et al. 2017

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Experimental investigation for characterizing and improving inlet designs in rotating detonation engines

Sisler¹

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Rotating detonation engines (RDEs) present great potential for significant improvement in efficiency for land based power generation systems, in addition to aircraft propulsion devices. They offer the advantage of a net pressure gain across the combustor, as well as high exhaust temperatures and less entropy production due to detonative combustion. These improvements provide direct correlation to improved overall efficiency and thermal efficiency of gas turbine engines. RDEs surpass their conventional combustor counterparts in terms of their geometric size and simpler mechanical design. Among many areas of much needed research to further the technology readiness level (TRL) of RDEs, the inlet design is paramount to the successful operation of a rotating detonation engine. The inlet is one of the central impetuses behind current RDE research.

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Andrew Sisler

Flow Visualization of Multi-Hole Film-Cooling Flow under Varying Freestream Turbulence Levels

Computationally Quantifying Loss Mechanisms in a Rotating Detonation Engine

Experimental Study of Rotating Detonation Combustor Performance under Preheat and Back Pressure Operation

Development of a Lab-Scale Experimental Testing Platform for Rotating Detonation Engine Inlets

Experimental investigation for characterizing and improving inlet designs in rotating detonation engines

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