Performance analysis of Single-Particle Model of a Lithium-Ion Cell
3 Angebote vergleichen
Bester Preis: € 34,10 (vom 02.01.2017)1
Performance analysis of Single-Particle Model of a Lithium-Ion Cell
DE HC NW
ISBN: 9783330010864 bzw. 333001086X, in Deutsch, Lap Lambert Academic Publishing, gebundenes Buch, neu.
Lieferung aus: Deutschland, Versandkostenfrei innerhalb von Deutschland.
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 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. Lieferzeit 1-2 Werktage.
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 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. Lieferzeit 1-2 Werktage.
2
Performance analysis of Single-Particle Model of a Lithium-Ion Cell
EN NW
ISBN: 9783330010864 bzw. 333001086X, in Englisch, neu.
Lieferung aus: Deutschland, Versandfertig innerhalb von 3 Wochen.
Performance analysis of Single-Particle Model of a Lithium-Ion Cell, 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.
Performance analysis of Single-Particle Model of a Lithium-Ion Cell, 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.
3
Symbolbild
Performance analysis of Single-Particle Model of a Lithium-Ion Cell (2016)
DE PB NW RP
ISBN: 9783330010864 bzw. 333001086X, in Deutsch, Lap Lambert Academic Publishing, Taschenbuch, neu, Nachdruck.
Lieferung aus: Deutschland, Versandkostenfrei.
Von Händler/Antiquariat, English-Book-Service Mannheim [1048135], Mannheim, Germany.
This item is printed on demand for shipment within 3 working days.
Von Händler/Antiquariat, English-Book-Service Mannheim [1048135], Mannheim, Germany.
This item is printed on demand for shipment within 3 working days.
Lade…