Abstract
Two time-varying linear state-space representations of the generally accepted physicochemical model (PCM) of a lithium-ion cell are used to estimate local and global states during different charging scenarios. In terms of computational speed and suitability towards recursive state observer models, the solid-phase diffusion in the PCM of an exemplaric MCMB/LiCoO2 lithium-ion cell is derived with the aid of two different numerical reduction methods in the form of a Polynomial Profile and an Eigenfunction Method. As a benchmark, the PCM using the original Duhamel Superposition Integral approximation serves for the comparison of accuracy and computational speed. A modified spatial discretization via the finite volume method improves handling of boundary conditions and guarantees accurate simulation results of the PCM even at a low level of spatial discretization. The Polynomial Profile allows for a significant speed-up in computational time whilst showing a poor prediction accuracy during dynamic load profiles. The Eigenfunction Method shows a comparable accuracy as the benchmark for all load profiles whilst resulting in an even higher computational effort. The two derived observer models incorporate the state-space representation of the reduced PCM applying both the Polynomial and Eigenfunction approach combined with an Extended Kalman Filter algorithm based on a novel initialization algorithm and conservation of lithium mass. The estimation results of both models show robust and quick reduction of the residual errors for both local and global states when considering the applied current and the resulting cell voltage of the benchmark model, as the underlying measurement signal. The carried out state estimation for a 4C constant charge current showed a regression of the cell voltage error to 1 mV within 30 s with an initial SOC error of 42.4% under a standard deviation of 10 mV and including process noise.
Highlights
Introduction and literature reviewThe high energy and power density compared to other battery chemistries [1] established the lithium-ion battery as the state of the art technology for electrical energy storage systems for a wide application field, ranging from small electronic devices up to large scale applications such as stationary storage systems or automotive battery packs [2]
The generally accepted pseudo two-dimensional physicochemical model (PCM) for lithium-ion batteries is used in this work for the simulation of constant and dynamic load scenarios
The non-linear differential algebraic equations were discretized in time via CrankNicolson formulation and the finite difference method with finite volume formulation was used for the fully-spatially-resolved PCM
Summary
The high energy and power density compared to other battery chemistries [1] established the lithium-ion battery as the state of the art technology for electrical energy storage systems for a wide application field, ranging from small electronic devices up to large scale applications such as stationary storage systems or automotive battery packs [2]. The manufacturing costs are still challenging [3], which slows down a market penetration to an economically competitive energy storage system especially in the automotive sector [3] To address this circumstance, current efforts [4] aim to push the price below US$200 per kW h or even lower for lithium-ion cells [2] within the few years. Size effects must be considered for an accurate observing and controlling of cells such as increased inhomogeneities for the local current, concentration, potentials and temperature within the cell. Considering electric vehicles, a more simple but very meaningful worst-case scenario would be a falsely predicted available range based on SOC and temperature estimation considering no local effects within large-sized cells, which would compound the issue of range anxiety of the customer. To the author’s best knowledge, the presented work is the first attempt to estimate local states of a fully-spatially-resolved PCM solved via the finite volume method (FVM) using a modified extended Kalman filter (EKF) which conserves lithium mass and the states’ physical interpretation along with their spatial distribution
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