Design and Selection of Innovative Primary Circulation Pumps for GEN-IV Lead Fast Reactors

Design and Selection of Innovative Primary Circulation Pumps for GEN-IV Lead Fast Reactors

Although Lead-cooled Fast Reactor (LFR) is not a new concept, it continues to be an example of innovation in the nuclear field. Recently, there has been strong interest in liquid lead (Pb) or liquid lead–bismuth eutectic (LBE) both critical and subcritical systems in a relevant number of Countries,...

Full description

Bibliographic Details
Main Authors: Walter Borreani, Alessandro Alemberti, Guglielmo Lomonaco, Fabrizio Magugliani, Paolo Saracco
Format: Article
Language:English
Published: MDPI AG 2017-12-01
Series:Energies
Subjects:
nuclear energy
LFR
Generation-IV
pumps
CFD
liquid metal
ALFRED
Online Access:https://www.mdpi.com/1996-1073/10/12/2079
id doaj-ba617fff952d4362a2f8ae5a41d5eb9a
record_format Article
spelling doaj-ba617fff952d4362a2f8ae5a41d5eb9a2020-11-24T20:46:28ZengMDPI AGEnergies1996-10732017-12-011012207910.3390/en10122079en10122079Design and Selection of Innovative Primary Circulation Pumps for GEN-IV Lead Fast ReactorsWalter Borreani0Alessandro Alemberti1Guglielmo Lomonaco2Fabrizio Magugliani3Paolo Saracco4Genoa Nuclear Research Group (GeNERG)—Department of Mechanical Engineering, Energy, Production, Transport and Mathematical Models (DIME)/Division of Thermal Engineering and Environmental Conditioning (TEC), University of Genova (UNIGE), Via All’Opera Pia 15/A, 16145 Genova, ItalyAnsaldo Nucleare, Corso F. M. Perrone 25, 16152 Genova, ItalyGenoa Nuclear Research Group (GeNERG)—Department of Mechanical Engineering, Energy, Production, Transport and Mathematical Models (DIME)/Division of Thermal Engineering and Environmental Conditioning (TEC), University of Genova (UNIGE), Via All’Opera Pia 15/A, 16145 Genova, ItalyAnsaldo Nucleare, Corso F. M. Perrone 25, 16152 Genova, ItalyNational Institute for Nuclear Physics (INFN), Via Dodecaneso 33, 16146 Genova, ItalyAlthough Lead-cooled Fast Reactor (LFR) is not a new concept, it continues to be an example of innovation in the nuclear field. Recently, there has been strong interest in liquid lead (Pb) or liquid lead–bismuth eutectic (LBE) both critical and subcritical systems in a relevant number of Countries, including studies performed in the frame of GENERATION-IV initiative. In this paper, the theoretical and computational findings for three different designs of Primary Circulation Pump (PCP) evolving liquid lead (namely the jet pump, the Archimedean pump and the blade pump) are presented with reference to the ALFRED (Advanced Lead Fast Reactor European Demonstrator) design. The pumps are first analyzed from the theoretical point of view and then modeled with a 3D CFD code. Required design performance of the pumps are approximatively around an effective head of 2 bar with a mass flow rate of 5000 kg/s. Taking into account the geometrical constraints of the reactor and the fluid dynamics characteristics of the molten lead, the maximum design velocity for molten lead fluid flow of 2 m/s may be exceeded giving rise to unacceptable erosion phenomena of the blade or rotating component of the primary pumping system. For this reason a deep investigation of non-conventional axial pumps has been performed. The results presented shows that the design of the jet pump looks like beyond the current technological feasibility while, once the mechanical challenges of the Archimedean (screw) pump and the fluid-dynamic issues of the blade pump will be addressed, both could represent viable solutions as PCP for ALFRED. Particularly, the blade pump shows the best performance in terms of pressure head generated in normal operation conditions as well as pressure drop in locked rotor conditions. Further optimizations (mainly for what the geometrical configuration is concerned) are still necessary.https://www.mdpi.com/1996-1073/10/12/2079nuclear energyLFRGeneration-IVpumpsCFDliquid metalALFRED
collection DOAJ
language English
format Article
sources DOAJ
author Walter Borreani
Alessandro Alemberti
Guglielmo Lomonaco
Fabrizio Magugliani
Paolo Saracco
spellingShingle Walter Borreani
Alessandro Alemberti
Guglielmo Lomonaco
Fabrizio Magugliani
Paolo Saracco
Design and Selection of Innovative Primary Circulation Pumps for GEN-IV Lead Fast Reactors
Energies
nuclear energy
LFR
Generation-IV
pumps
CFD
liquid metal
ALFRED
author_facet Walter Borreani
Alessandro Alemberti
Guglielmo Lomonaco
Fabrizio Magugliani
Paolo Saracco
author_sort Walter Borreani
title Design and Selection of Innovative Primary Circulation Pumps for GEN-IV Lead Fast Reactors
title_short Design and Selection of Innovative Primary Circulation Pumps for GEN-IV Lead Fast Reactors
title_full Design and Selection of Innovative Primary Circulation Pumps for GEN-IV Lead Fast Reactors
title_fullStr Design and Selection of Innovative Primary Circulation Pumps for GEN-IV Lead Fast Reactors
title_full_unstemmed Design and Selection of Innovative Primary Circulation Pumps for GEN-IV Lead Fast Reactors
title_sort design and selection of innovative primary circulation pumps for gen-iv lead fast reactors
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2017-12-01
description Although Lead-cooled Fast Reactor (LFR) is not a new concept, it continues to be an example of innovation in the nuclear field. Recently, there has been strong interest in liquid lead (Pb) or liquid lead–bismuth eutectic (LBE) both critical and subcritical systems in a relevant number of Countries, including studies performed in the frame of GENERATION-IV initiative. In this paper, the theoretical and computational findings for three different designs of Primary Circulation Pump (PCP) evolving liquid lead (namely the jet pump, the Archimedean pump and the blade pump) are presented with reference to the ALFRED (Advanced Lead Fast Reactor European Demonstrator) design. The pumps are first analyzed from the theoretical point of view and then modeled with a 3D CFD code. Required design performance of the pumps are approximatively around an effective head of 2 bar with a mass flow rate of 5000 kg/s. Taking into account the geometrical constraints of the reactor and the fluid dynamics characteristics of the molten lead, the maximum design velocity for molten lead fluid flow of 2 m/s may be exceeded giving rise to unacceptable erosion phenomena of the blade or rotating component of the primary pumping system. For this reason a deep investigation of non-conventional axial pumps has been performed. The results presented shows that the design of the jet pump looks like beyond the current technological feasibility while, once the mechanical challenges of the Archimedean (screw) pump and the fluid-dynamic issues of the blade pump will be addressed, both could represent viable solutions as PCP for ALFRED. Particularly, the blade pump shows the best performance in terms of pressure head generated in normal operation conditions as well as pressure drop in locked rotor conditions. Further optimizations (mainly for what the geometrical configuration is concerned) are still necessary.
topic nuclear energy
LFR
Generation-IV
pumps
CFD
liquid metal
ALFRED
url https://www.mdpi.com/1996-1073/10/12/2079
work_keys_str_mv AT walterborreani designandselectionofinnovativeprimarycirculationpumpsforgenivleadfastreactors
AT alessandroalemberti designandselectionofinnovativeprimarycirculationpumpsforgenivleadfastreactors
AT guglielmolomonaco designandselectionofinnovativeprimarycirculationpumpsforgenivleadfastreactors
AT fabriziomagugliani designandselectionofinnovativeprimarycirculationpumpsforgenivleadfastreactors
AT paolosaracco designandselectionofinnovativeprimarycirculationpumpsforgenivleadfastreactors
_version_ 1716812533826846720

Similar Items