In turbomachinery, the steady adjoint method has been successfully used for the computation of derivatives of various objective functions with respect to design variables in gradient-based optimization. However, the continuous advances in computing power and the accuracy limitations of the steady-state assumption lead toward the transition to unsteady computational fluid dynamics (CFD) computations in the industrial design process. Previous work on unsteady adjoint for turbomachinery applications almost exclusively rely upon frequency-domain methods, for both the flow and adjoint equations. In contrast, in this paper, the development the discrete adjoint to the unsteady Reynolds-averaged Navier–Stokes (URANS) solver for three-dimensional (3D) multirow applications, in the time-domain, is presented. The adjoint equations are derived along with the adjoint to the five-stage Runge–Kutta scheme. Communication between adjacent rows is achieved by the adjoint sliding interface method. An optimization workflow that uses unsteady flow and adjoint solvers is presented and tested in two cases, with objective functions accounting for the transient flow in a turbine vane and the periodic flow in a compressor three-row setup.
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August 2018
Research-Article
Employing the Time-Domain Unsteady Discrete Adjoint Method for Shape Optimization of Three-Dimensional Multirow Turbomachinery Configurations
Georgios Ntanakas,
Georgios Ntanakas
Rolls-Royce Deutschland,
Blankenfelde-Mahlow 15827, Germany;
Parallel CFD & Optimization Unit,
Lab of Thermal Turbomachines,
School of Mechanical Engineering,
National Technical University of Athens,
Athens 15780, Greece
e-mail: gntanak@central.ntua.gr
Blankenfelde-Mahlow 15827, Germany;
Parallel CFD & Optimization Unit,
Lab of Thermal Turbomachines,
School of Mechanical Engineering,
National Technical University of Athens,
Athens 15780, Greece
e-mail: gntanak@central.ntua.gr
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Kyriakos C. Giannakoglou
Kyriakos C. Giannakoglou
Parallel CFD & Optimization Unit,
Lab of Thermal Turbomachines,
School of Mechanical Engineering,
National Technical University of Athens,
Athens 15780, Greece
e-mail: kgianna@central.ntua.gr
Lab of Thermal Turbomachines,
School of Mechanical Engineering,
National Technical University of Athens,
Athens 15780, Greece
e-mail: kgianna@central.ntua.gr
Search for other works by this author on:
Georgios Ntanakas
Rolls-Royce Deutschland,
Blankenfelde-Mahlow 15827, Germany;
Parallel CFD & Optimization Unit,
Lab of Thermal Turbomachines,
School of Mechanical Engineering,
National Technical University of Athens,
Athens 15780, Greece
e-mail: gntanak@central.ntua.gr
Blankenfelde-Mahlow 15827, Germany;
Parallel CFD & Optimization Unit,
Lab of Thermal Turbomachines,
School of Mechanical Engineering,
National Technical University of Athens,
Athens 15780, Greece
e-mail: gntanak@central.ntua.gr
Marcus Meyer
Kyriakos C. Giannakoglou
Parallel CFD & Optimization Unit,
Lab of Thermal Turbomachines,
School of Mechanical Engineering,
National Technical University of Athens,
Athens 15780, Greece
e-mail: kgianna@central.ntua.gr
Lab of Thermal Turbomachines,
School of Mechanical Engineering,
National Technical University of Athens,
Athens 15780, Greece
e-mail: kgianna@central.ntua.gr
Manuscript received December 3, 2017; final manuscript received June 12, 2018; published online July 26, 2018. Assoc. Editor: Li He.
J. Turbomach. Aug 2018, 140(8): 081006 (11 pages)
Published Online: July 26, 2018
Article history
Received:
December 3, 2017
Revised:
June 12, 2018
Citation
Ntanakas, G., Meyer, M., and Giannakoglou, K. C. (July 26, 2018). "Employing the Time-Domain Unsteady Discrete Adjoint Method for Shape Optimization of Three-Dimensional Multirow Turbomachinery Configurations." ASME. J. Turbomach. August 2018; 140(8): 081006. https://doi.org/10.1115/1.4040564
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