Synopsis
The aim of study is to predict the performance of lithium-ion cells using the single particle representation of battery electrode model. The model is developed starting from the concentration solution theory and porous-electrode formulation, with Fick’s law governing the diffusion of ions in the solid electrode. Since the solution of the governing equations is difficult due to their non-linear nature, simplifying assumptions are made that considerably reduce the computational time needed to predict cell performance. The model is then used to determine the concentration of lithium in solid phase and the electrode potential, assuming that the lithium concentration remains fixed in electrolyte. Further this model is compared with the pseudo two- dimensional model to simulate cyclic performance of lithium-ion cells under various operating conditions. The single particle modelling is studied for the degradation and its effect on the cyclic performance of lithium ion cell. The degradation of lithium-ion cells as a function of cycle number and parasitic reaction current density was also studied.
Les informations fournies dans la section « Synopsis » peuvent faire référence à une autre édition de ce titre.
Présentation de l'éditeur
The aim of study is to predict the performance of lithium-ion cells using the single particle representation of battery electrode model. The model is developed starting from the concentration solution theory and porous-electrode formulation, with Fick’s law governing the diffusion of ions in the solid electrode. Since the solution of the governing equations is difficult due to their non-linear nature, simplifying assumptions are made that considerably reduce the computational time needed to predict cell performance. The model is then used to determine the concentration of lithium in solid phase and the electrode potential, assuming that the lithium concentration remains fixed in electrolyte. Further this model is compared with the pseudo two- dimensional model to simulate cyclic performance of lithium-ion cells under various operating conditions. The single particle modelling is studied for the degradation and its effect on the cyclic performance of lithium ion cell. The degradation of lithium-ion cells as a function of cycle number and parasitic reaction current density was also studied.
Biographie de l'auteur
Dr. Alok Manas Dubey is a Professor at the Department of Mechanical Engineering Raj Kumar Goel Institute of Technology, Ghaziabad. He possess more than 15 years of teaching, research and industrial experience with leading institutions/ organizations. Prof. Alok Manas Dubey has over 10 articles published in prestigious SCI journals.
Les informations fournies dans la section « A propos du livre » peuvent faire référence à une autre édition de ce titre.
Résultats de recherche pour Performance analysis of Single-Particle Model of a...
Image fournie par le vendeur
Performance analysis of Single-Particle Model of a Lithium-Ion Cell
Edité par
LAP LAMBERT Academic Publishing Nov 2016, 2016
ISBN 10 : 333001086X
ISBN 13 : 9783330010864
Neuf
Taschenbuch
Vendeur : BuchWeltWeit Ludwig Meier e.K., Bergisch Gladbach, Allemagne
Évaluation du vendeur 5 sur 5 étoiles
Taschenbuch. Etat : Neu. This item is printed on demand - it takes 3-4 days longer - Neuware -The aim of study is to predict the performance of lithium-ion cells using the single particle representation of battery electrode model. The model is developed starting from the concentration solution theory and porous-electrode formulation, with Fick's law governing the diffusion of ions in the solid electrode. Since the solution of the governing equations is difficult due to their non-linear nature, simplifying assumptions are made that considerably reduce the computational time needed to predict cell performance. The model is then used to determine the concentration of lithium in solid phase and the electrode potential, assuming that the lithium concentration remains fixed in electrolyte. Further this model is compared with the pseudo two- dimensional model to simulate cyclic performance of lithium-ion cells under various operating conditions. The single particle modelling is studied for the degradation and its effect on the cyclic performance of lithium ion cell. The degradation of lithium-ion cells as a function of cycle number and parasitic reaction current density was also studied. 60 pp. Englisch. N° de réf. du vendeur 9783330010864
Acheter neuf
EUR 35,90
Expédition à EUR 23
Expédition depuis Allemagne vers Etats-Unis
Expédition depuis Allemagne vers Etats-Unis
Quantité disponible : 2 disponible(s)
Image d'archives
Performance analysis of Single-Particle Model of a Lithium-Ion Cell
Edité par
LAP LAMBERT Academic Publishing, 2016
ISBN 10 : 333001086X
ISBN 13 : 9783330010864
Neuf
Paperback
Vendeur : Revaluation Books, Exeter, Royaume-Uni
Évaluation du vendeur 5 sur 5 étoiles
Paperback. Etat : Brand New. 60 pages. 8.66x5.91x0.14 inches. In Stock. N° de réf. du vendeur 333001086X
Acheter neuf
EUR 59,67
Expédition à EUR 11,58
Expédition depuis Royaume-Uni vers Etats-Unis
Expédition depuis Royaume-Uni vers Etats-Unis
Quantité disponible : 1 disponible(s)
Image fournie par le vendeur
Performance analysis of Single-Particle Model of a Lithium-Ion Cell
Edité par
LAP LAMBERT Academic Publishing, 2016
ISBN 10 : 333001086X
ISBN 13 : 9783330010864
Neuf
Couverture souple
Vendeur : moluna, Greven, Allemagne
Évaluation du vendeur 5 sur 5 étoiles
Etat : New. Dieser Artikel ist ein Print on Demand Artikel und wird nach Ihrer Bestellung fuer Sie gedruckt. Autor/Autorin: Dubey Alok ManasDr. Alok Manas Dubey is a Professor at the Department of Mechanical Engineering Raj Kumar Goel Institute of Technology, Ghaziabad. He possess more than 15 years of teaching, research and industrial experience with lea. N° de réf. du vendeur 158421704
Acheter neuf
EUR 31,27
Expédition à EUR 48,99
Expédition depuis Allemagne vers Etats-Unis
Expédition depuis Allemagne vers Etats-Unis
Quantité disponible : Plus de 20 disponibles
Image fournie par le vendeur
Performance analysis of Single-Particle Model of a Lithium-Ion Cell
Edité par
LAP LAMBERT Academic Publishing Nov 2016, 2016
ISBN 10 : 333001086X
ISBN 13 : 9783330010864
Neuf
Taschenbuch
Vendeur : buchversandmimpf2000, Emtmannsberg, BAYE, Allemagne
Évaluation du vendeur 5 sur 5 étoiles
Taschenbuch. Etat : Neu. This item is printed on demand - Print on Demand Titel. Neuware -The aim of study is to predict the performance of lithium-ion cells using the single particle representation of battery electrode model. The model is developed starting from the concentration solution theory and porous-electrode formulation, with Fick's law governing the diffusion of ions in the solid electrode. Since the solution of the governing equations is difficult due to their non-linear nature, simplifying assumptions are made that considerably reduce the computational time needed to predict cell performance. The model is then used to determine the concentration of lithium in solid phase and the electrode potential, assuming that the lithium concentration remains fixed in electrolyte. Further this model is compared with the pseudo two- dimensional model to simulate cyclic performance of lithium-ion cells under various operating conditions. The single particle modelling is studied for the degradation and its effect on the cyclic performance of lithium ion cell. The degradation of lithium-ion cells as a function of cycle number and parasitic reaction current density was also studied.VDM Verlag, Dudweiler Landstraße 99, 66123 Saarbrücken 60 pp. Englisch. N° de réf. du vendeur 9783330010864
Acheter neuf
EUR 35,90
Expédition à EUR 60
Expédition depuis Allemagne vers Etats-Unis
Expédition depuis Allemagne vers Etats-Unis
Quantité disponible : 1 disponible(s)
Image fournie par le vendeur
Performance analysis of Single-Particle Model of a Lithium-Ion Cell
Edité par
LAP LAMBERT Academic Publishing, 2016
ISBN 10 : 333001086X
ISBN 13 : 9783330010864
Neuf
Taschenbuch
Vendeur : AHA-BUCH GmbH, Einbeck, Allemagne
Évaluation du vendeur 5 sur 5 étoiles
Taschenbuch. Etat : Neu. nach der Bestellung gedruckt Neuware - Printed after ordering - The aim of study is to predict the performance of lithium-ion cells using the single particle representation of battery electrode model. The model is developed starting from the concentration solution theory and porous-electrode formulation, with Fick's law governing the diffusion of ions in the solid electrode. Since the solution of the governing equations is difficult due to their non-linear nature, simplifying assumptions are made that considerably reduce the computational time needed to predict cell performance. The model is then used to determine the concentration of lithium in solid phase and the electrode potential, assuming that the lithium concentration remains fixed in electrolyte. Further this model is compared with the pseudo two- dimensional model to simulate cyclic performance of lithium-ion cells under various operating conditions. The single particle modelling is studied for the degradation and its effect on the cyclic performance of lithium ion cell. The degradation of lithium-ion cells as a function of cycle number and parasitic reaction current density was also studied. N° de réf. du vendeur 9783330010864
Acheter neuf
EUR 35,90
Expédition à EUR 60,54
Expédition depuis Allemagne vers Etats-Unis
Expédition depuis Allemagne vers Etats-Unis
Quantité disponible : 1 disponible(s)
Image fournie par le vendeur
Performance analysis of Single-Particle Model of a Lithium-Ion Cell
Edité par
LAP LAMBERT Academic Publishing, 2016
ISBN 10 : 333001086X
ISBN 13 : 9783330010864
Neuf
Taschenbuch
Vendeur : preigu, Osnabrück, Allemagne
Évaluation du vendeur 5 sur 5 étoiles
Taschenbuch. Etat : Neu. Performance analysis of Single-Particle Model of a Lithium-Ion Cell | Alok Manas Dubey (u. a.) | Taschenbuch | 60 S. | Englisch | 2016 | LAP LAMBERT Academic Publishing | EAN 9783330010864 | Verantwortliche Person für die EU: BoD - Books on Demand, In de Tarpen 42, 22848 Norderstedt, info[at]bod[dot]de | Anbieter: preigu. N° de réf. du vendeur 108009050
Acheter neuf
EUR 33,20
Expédition à EUR 70
Expédition depuis Allemagne vers Etats-Unis
Expédition depuis Allemagne vers Etats-Unis
Quantité disponible : 5 disponible(s)