Computer simulation of flow at part load in a laboratory model of Kaplan hydroturbine by RANS, des and les

A. Minakov; D. Platonov; I. Litvinov; K. Hanjalić

Computer simulation of flow at part load in a laboratory model of Kaplan hydroturbine by RANS, des and les

A. Minakov, D. Platonov, I. Litvinov, K. Hanjalić

Research output: Contribution to journal › Conference article › peer-review

1 Scopus citations

Abstract

We presents some results of numerical simulation of flow in a 60:1 scaled-down laboratory model of a Kaplan hydroturbine at a part load of about 40% nominal flow rate, using several RANS models (realizable k-ϵ k-ω SST EVMs and LRR RSM), DES (all on 2 mill cells) and LES (on 6 mill cells). Unlike the linear eddy viscosity models, the RSM, DES and LES all reproduced well the available mean velocity axial and tangential components and the rsm of their fluctuations in the draft tube diffusor. Despite a relatively coarse mesh that did not resolve well the near-wall region, LES, DES and RSM reproduced well the intrinsic flow unsteadiness and the dominant flow structures, all capturing a double rope pattern in the cone behind the turbine runner.

Original language	English
Pages (from-to)	803-806
Number of pages	4
Journal	Proceedings of the International Symposium on Turbulence, Heat and Mass Transfer
Volume	0
State	Published - 2015
Externally published	Yes
Event	8th International Symposium on Turbulence, Heat and Mass Transfer, THMT 2015 - Sarajevo, Bosnia and Herzegovina Duration: 15 Sep 2015 → 18 Sep 2015

Funding

Funders	Funder number
Russian Science Foundation	14-29-00203

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Cite this

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abstract = "We presents some results of numerical simulation of flow in a 60:1 scaled-down laboratory model of a Kaplan hydroturbine at a part load of about 40% nominal flow rate, using several RANS models (realizable k-ϵ k-ω SST EVMs and LRR RSM), DES (all on 2 mill cells) and LES (on 6 mill cells). Unlike the linear eddy viscosity models, the RSM, DES and LES all reproduced well the available mean velocity axial and tangential components and the rsm of their fluctuations in the draft tube diffusor. Despite a relatively coarse mesh that did not resolve well the near-wall region, LES, DES and RSM reproduced well the intrinsic flow unsteadiness and the dominant flow structures, all capturing a double rope pattern in the cone behind the turbine runner.",

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AU - Minakov, A.

AU - Platonov, D.

AU - Litvinov, I.

AU - Hanjalić, K.

PY - 2015

Y1 - 2015

N2 - We presents some results of numerical simulation of flow in a 60:1 scaled-down laboratory model of a Kaplan hydroturbine at a part load of about 40% nominal flow rate, using several RANS models (realizable k-ϵ k-ω SST EVMs and LRR RSM), DES (all on 2 mill cells) and LES (on 6 mill cells). Unlike the linear eddy viscosity models, the RSM, DES and LES all reproduced well the available mean velocity axial and tangential components and the rsm of their fluctuations in the draft tube diffusor. Despite a relatively coarse mesh that did not resolve well the near-wall region, LES, DES and RSM reproduced well the intrinsic flow unsteadiness and the dominant flow structures, all capturing a double rope pattern in the cone behind the turbine runner.

AB - We presents some results of numerical simulation of flow in a 60:1 scaled-down laboratory model of a Kaplan hydroturbine at a part load of about 40% nominal flow rate, using several RANS models (realizable k-ϵ k-ω SST EVMs and LRR RSM), DES (all on 2 mill cells) and LES (on 6 mill cells). Unlike the linear eddy viscosity models, the RSM, DES and LES all reproduced well the available mean velocity axial and tangential components and the rsm of their fluctuations in the draft tube diffusor. Despite a relatively coarse mesh that did not resolve well the near-wall region, LES, DES and RSM reproduced well the intrinsic flow unsteadiness and the dominant flow structures, all capturing a double rope pattern in the cone behind the turbine runner.

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JO - Proceedings of the International Symposium on Turbulence, Heat and Mass Transfer

JF - Proceedings of the International Symposium on Turbulence, Heat and Mass Transfer

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Y2 - 15 September 2015 through 18 September 2015

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Computer simulation of flow at part load in a laboratory model of Kaplan hydroturbine by RANS, des and les

Abstract

Funding

UN SDGs

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