CA2874632C - Estimating core temperatures of battery cells in a battery pack - Google Patents
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/05—Accumulators with non-aqueous electrolyte
- H01M10/052—Li-accumulators
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K7/00—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements
- G01K7/42—Circuits effecting compensation of thermal inertia; Circuits for predicting the stationary value of a temperature
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R31/00—Arrangements for testing electric properties; Arrangements for locating electric faults; Arrangements for electrical testing characterised by what is being tested not provided for elsewhere
- G01R31/36—Arrangements for testing, measuring or monitoring the electrical condition of accumulators or electric batteries, e.g. capacity or state of charge [SoC]
- G01R31/3644—Constructional arrangements
- G01R31/3648—Constructional arrangements comprising digital calculation means, e.g. for performing an algorithm
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R31/00—Arrangements for testing electric properties; Arrangements for locating electric faults; Arrangements for electrical testing characterised by what is being tested not provided for elsewhere
- G01R31/36—Arrangements for testing, measuring or monitoring the electrical condition of accumulators or electric batteries, e.g. capacity or state of charge [SoC]
- G01R31/389—Measuring internal impedance, internal conductance or related variables
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/48—Accumulators combined with arrangements for measuring, testing or indicating the condition of cells, e.g. the level or density of the electrolyte
- H01M10/482—Accumulators combined with arrangements for measuring, testing or indicating the condition of cells, e.g. the level or density of the electrolyte for several batteries or cells simultaneously or sequentially
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/48—Accumulators combined with arrangements for measuring, testing or indicating the condition of cells, e.g. the level or density of the electrolyte
- H01M10/486—Accumulators combined with arrangements for measuring, testing or indicating the condition of cells, e.g. the level or density of the electrolyte for measuring temperature
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/60—Heating or cooling; Temperature control
- H01M10/63—Control systems
- H01M10/633—Control systems characterised by algorithms, flow charts, software details or the like
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/60—Heating or cooling; Temperature control
- H01M10/65—Means for temperature control structurally associated with the cells
- H01M10/655—Solid structures for heat exchange or heat conduction
- H01M10/6556—Solid parts with flow channel passages or pipes for heat exchange
- H01M10/6557—Solid parts with flow channel passages or pipes for heat exchange arranged between the cells
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/60—Other road transportation technologies with climate change mitigation effect
- Y02T10/70—Energy storage systems for electromobility, e.g. batteries
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Abstract
Description
BATTERY CELLS IN A BATTERY PACK
TECHNICAL FIELD
This invention relates generally to batteries, and particularly relates to ways of estimating temperatures of battery cells in a battery pack, such as core temperatures.
BACKGROUND OF THE INVENTION
Batteries such as lithium-ion batteries are a common source of electrical energy for mobile phones, tablet and laptop computers, hybrid electric vehicles (HEVs), plug-in hybrid electric vehicles (PHEVs), battery electric vehicles (BEVs), industrial equipment such as forklifts and robots, stationary power generators such as solar power generators and wind power generators, as well as other applications. A lithium-ion battery in these types of applications typically includes a battery pack made up of numerous individual battery cells¨sometimes hundreds or thousands of cells.
During use, the charging and discharging performance and the life of the batteries can degrade appreciably due to rising internal core temperatures of the battery cells. In some cases, lithium-ion batteries have been shown to exhibit a somewhat confined window of temperatures in which they can effectively perform (e.g., -10 C to 50 C).
Accordingly, attempts have been made to monitor the internal core temperatures of battery cells in order to better manage cooling systems of the battery pack and hence the temperatures of the batteries.
Past attempts, however, have been fraught with shortcomings and can be largely inaccurate, unreliable, and in some cases impractical. In one example, a surface temperature of a battery cell is measured and taken as its core temperature.
But this can be grossly inaccurate as temperatures between the surface and the core can differ by as much as 30 C. In another example, temperature sensors are installed inside of a battery cell's internal core to take temperature measurements at the core. But this can be impractical due to the accompanying cost for equipping the hundreds or even thousands of battery cells often found in the types of applications mentioned above.
SUMMARY OF THE INVENTION
According to one embodiment, a method of estimating core temperatures of battery cells in a battery pack includes several steps. In one step, a surface temperature of less than all of the battery cells in the battery pack is dynamically received, a current of the less than all battery cells is dynamically received, an inlet temperature of coolant provided to the battery pack is dynamically received, and a flow rate or velocity of the coolant is dynamically received. In another step, a cell-lumped internal electrical resistance of the less than all battery cells is dynamically estimated, a cell-lumped conduction resistance between a core and a surface of the less than all battery cells is dynamically estimated, and a cell-lumped convection resistance between the surface of the less than all battery cells and the coolant is dynamically estimated; the estimations in this step are based in part or more upon the received values of the previous step. In yet another step, a core temperature of the less than all battery cells is dynamically estimated based in part or more upon the received and estimated values of the previous steps. And in another step, thermal energy transfer effects between the coolant and the battery cells are used, thermal energy transfer effects among the battery cells are used, and the estimated core temperature values of the previous step are used, all in order to estimate the core temperatures for all of the battery cells in the battery pack.
According to another embodiment, a method of estimating core temperatures of battery cells in a battery pack includes several steps. In one step, a surface temperature of one or more battery cells in the battery pack is dynamically received, a current of the one or more battery cells is dynamically received, an inlet temperature of coolant provided for the battery pack is dynamically received, and a flow rate or velocity of the coolant is dynamically received. In another step, a cell-lumped internal electrical resistance of the one or more battery cells is dynamically estimated, a cell-lumped conduction resistance between a core and a surface of the one or more battery cells is dynamically estimated, and a cell-lumped convection resistance between the surface of the one or more battery cells and the coolant is dynamically estimated; the estimations in this step are based in part or more upon the received values of the previous step. In yet another step, a core temperature of the one or more battery cells is dynamically estimated, and a surface temperature of the one or more battery cells is dynamically estimated; the estimations in this step are based in part or more upon the received and
According to another embodiment, a system for estimating core temperatures of battery cells in a battery pack includes one or more sensors, a controller, and a battery thermal management assembly. The one or more sensors are coupled to one or more battery cells of the battery pack in order to measure a surface temperature of the one or more battery cells. The controller is coupled, directly or indirectly, to the one or more sensors in order to receive the measured surface temperature. The controller performs the steps of: i) receiving a current of the one or more battery cells, receiving an inlet temperature of coolant provided to the battery pack, and receiving a flow rate or velocity of the coolant; ii) estimating a cell-lumped internal electrical resistance of the one or more battery cells, estimating a cell-lumped conduction resistance between a core and a surface of the one or more battery cells, and estimating a cell-lumped convection resistance between the surface of the one or more battery cells and the coolant; the estimations in this step are based in part or more upon the measured surface temperature and the received values of step i); iii) estimating a core temperature of the one or more battery cells based in part or more upon the measured surface temperature, the received values of step i), and the estimated values of step ii); and iv) using thermal energy transfer effects between the coolant and the battery cells, using thermal energy transfer effects among the battery cells, and using the estimated core temperature values of step iii), all in order to estimate the core temperatures for all of the battery cells in the battery pack. The battery thermal management assembly is electrically coupled, directly or indirectly, to the controller and is controlled by the controller based in part or more upon the estimated core temperatures for all of the battery cells in the battery pack.
BRIEF DESCRIPTION OF THE DRAWINGS
Preferred exemplary embodiments of the invention will hereinafter be described in conjunction with the appended drawings, wherein like designations denote like elements, and wherein:
Figure 2A is a graph comparing simulated results of internal electrical resistance growth with internal electrical resistance growth identified by an embodiment of an identification algorithm;
Figure 2B is a graph comparing average internal electrical resistance growth of simulated results with average internal electrical resistance growth identified by the identification algorithm;
Figure 3 is a diagrammatic view showing thermal energy transfer effects between two individual battery cells, and between coolant and the battery cells;
Figure 4A is a graph showing simulated results of convergence times of estimated surface temperatures using a closed loop observer with real surface temperatures, and of convergence times of estimated surface temperatures using an open loop observer with real surface temperatures;
Figure 4B is a graph showing simulated results of convergence times of estimated core temperatures using a closed loop observer with real core temperatures, and of convergence times of estimated core temperatures using an open loop observer with real core temperatures;
Figure 5A is a diagrammatic view showing state observability conditions based on a location of temperature sensors among battery cells; and Figure 5B is a diagrammatic view similar to figure 5A, but with temperature sensors at different locations than those in figure 5A.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
The present disclosure provides embodiments of methods and systems for estimating a core temperature in a battery cell of a battery pack in a way that is more accurate, precise, and reliable than previously known. The core temperature estimation
Furthermore, the methods and systems can provide an approximate determination of the state of health (SOH) of the battery pack based on the growth of internal electrical resistance within the battery cells over time. And lastly, the methods and systems disclosed herein can provide temperature sensor deployment strategies among the battery cells in the battery pack such as the actual quantity of sensors and placement and location of the sensors on the battery cells, and can provide certain design guidance for the cells such as the construction of a connection tab between two cells. All of this is described in greater detail below.
In general, the methods and systems detailed in this description utilize various algorithms, models, formulae, and other functionality that can be stored and performed in a controller such as an electronic control unit (ECU) in a vehicle. As will be known by skilled artisans, the controller can have hardware, software, firmware, or other like components configured and programmed to perform these functions, and can employ memory components, processing components, logic components, lookup tables, or other like components when performing the functions. Also, while this description provides examples of algorithms, models, formulae, and other functionality used to perform the methods and systems herein, skilled artisans will appreciate that other suitable algorithms, models, and formulae may be used as alternatives to perform the
The sensors and other measurement components can be electrically coupled to the controller¨via wires, wirelessly, or some other way¨in order to send signals and data for reception by the controller. And while the methods and systems herein are described in the context of lithium-ion batteries, the methods and systems are applicable with to batteries of other types such as nickel-metal hydride batteries, and may be performed with battery cells of different sizes, shapes, arrangements, architectures, and connectivity. For example, the methods and systems may be performed with cylindrical batteries, prismatic batteries, batteries with parallel circuitry, and batteries with series circuitry.
Once estimated, the information provided as output by the methods and systems can be used to manage charging, discharging, cooling, and other operations of the battery pack. As an example, during a charging process, if an estimated core temperature is higher than a predetermined threshold, a charging voltage of the battery pack can be reduced in order to prevent overheating of the battery pack. As another example, if the estimated core temperature is higher than the predetermined threshold, a cooling process can be initiated or augmented in order to bring the core temperature below the predetermined threshold. In the example of a vehicle with a lithium-ion battery, the vehicle can be equipped with a battery thermal management system and assembly. The battery thermal management system can be electrically coupled to its accompanying controller for assisting control of the system's operation, and can include a fan, pump, or other device for moving a coolant such as air or liquid around and through the battery pack. The information provided as output could then be used, for example, to turn the battery thermal management system on or off, or adjust its operating state such as from a low level to a higher level of operation.
Still, the output information could be used for other purposes and in other ways.
Referring now to figure 1, in this embodiment the methods and systems for estimating core temperatures in battery cells of a battery pack involves a parameter
Governing equations for these states in this embodiment are:
C ¨ D ¨ I2R + 7:-s--T, c c e Rc Tf. ¨ T, 7's_Tc CA = ¨ + ¨
R i?
u c Heat generated in a core 18 of the battery cell 16 is approximated as a concentrated source of Joule loss, computed as the product of current I
squared and internal electrical resistance R.. Thermal energy transfer effects between the core 18 and a surface 20 of the battery cell 16 is modeled by heat conduction over a thermal resistance R., which is a lumped parameter aggregating the conduction and contact thermal resistance across what-is-oftentimes compact and inhomogeneous materials of the core. A convection resistance R. is modeled between the surface 20 and a coolant 22 provided to the larger battery pack; the value of the convection resistance R. can be a function of a rate of coolant flow or velocity of coolant and, in some cases, the coolant flow rate is adjustable depending on the temperature of the battery pack; in this embodiment, it can be modeled as a constant as if the coolant flow rate is fixed in order to accommodate a maximum cooling capacity. Further, the rates of temperature change of the core 18 and the surface 20 depend on their respective lumped heat capacities.
That is, a heat capacity C. of the core 18, and a heat capacity Cs of the surface 20.
Accordingly, in this embodiment, parameters of the thermal model 14 include Re, Re, R5, G, and C. Because the values of the parameters cannot always be easily calculated, model identification techniques are used to obtain lumped phenomenological values of the parameters based upon measurable inputs and outputs of the thermal model 14.
Parameterization Methodology In linear model identification techniques, a parametric model z = eT 0
m2 P = ¨P , P
in,.
E = Z ¨ OT CICI
m2 = 1+ (pro where m is a normalization factor that enhances the robustness of parameter identification, P is the covariance matrix, and E is the error in observation.
In this embodiment, in order to make the observation z and the regressors 0 proper or causal, a filter ¨il(s) can be applied. The parametric model then becomes z 0 _ = eT _ A A
In one embodiment, in order to help ensure convergence and robustness of the identification, regressors cp are stationary signals and satisfy persistent excitation (PE) conditions. The PE conditions are satisfied if there exist some time interval To, and positive number ai and ao, such that 1 ti-To ai/m U(t) = ¨J o ( 1 ) 49 7 . (r)cli aolm V t. 0 Tot where IM is the identity matrix with the same dimension as U(t).
In other embodiments not described here in detail, the parametric model could employ other algorithms for parameter identification such as gradient search, or a non-recursive least squares algorithm could be applied. The above is merely one example.
Accordingly, a parametric model for identification can be derived by taking the Laplace transformation of the Tc and Ts state equations and replacing unmeasured Tc with measured signals I, Tr, and Ts R... 1 1 1 s2T5 ¨ sT5'0 =C C...R 12 +CCRR _______ (Tf Ts) +C R s(Tf Ts) ____ ((Cc c s c cscu s u C C R
c s c + Cs)sTs ¨ CsTs,o¨ CcTc,o) where Ts,0 and Tc,0 are the initial surface and core temperatures. When the initial core temperature Tc,o is considered to be the same as the initial surface temperature Ts,o, as when the larger battery pack is started from thermal equilibrium, the equation becomes (equation (ii)) Re , CcC,RcRu 1 , Cc. + Cs s2T, ¨ sTs'o = CcCsk I' + ________________ (Tf Ts) CcC,Re (sTs ¨Ts,o) +¨Ru 1 , kTf s ¨Ts) Cs It is assumed here that Tr is regulated as a steady output of the battery thermal management system and hence sTr=0, giving (equation (iii)) Re 1 C + C
, c s 1 s27s - sTso = CCsR CcCsRcRu 12 + (Tf ¨ Ts) ¨ CCsIt k.-- +¨)(sTs ¨ T5,0) ' cc cc CsRu If Tr is a time-varying input to the model, sTr should not be dropped in this embodiment. Here, Tr can also be used as an input excitation in the parametric model.
A second order filter can be applied to the observation and the regressors in the immediately above equation in order to make them proper. The second order filter takes the form _ = _____________________________________________ A(s) (s + .1.1)(s + A2)
For the parametric model, then s2T ¨ sTs,0 A(s) Tf Ts sT ¨ Ts 01T
4)(s) = = _____ s A(s) A(s) A(s) = [a (3 y17.
where Re a = ______________________________________ r 1,0,s/1c = CcC,RcRõ
Cc + Cs 1 Y = _______ ¨) CcCsRc CsR, In one embodiment of implementation, the parametric model is formulated along with signals z and in the time domain based on equations (i), or in the discrete time domain based on equivalent formula. For example, z(t), whose Laplace transform s2T,--sT
is /los) s', can be obtained by calculating the convolution of Ts(t)-To and the inverse s2 Laplace transform of ¨.In this way, calculation of the 2nd order derivative of Ts, s2T5, which can be corrupted by noises, is avoided.
By using the parametric model in equation (iii), only three lumped parameters, a, and y, can be identified under the condition of persistent input excitation. Prior knowledge of two of the physical parameters are to be assumed so as to determine a set of unique solution for the original five physical parameters, Cc, Cs, Re, Re, and X, from a, 13, and y. Of the five physical parameters, the internal electrical resistance Re may vary due to aging and is preferably identified online, the conduction resistance Re is not
Accordingly, the heat capacities Cc and C, can be selected as the presumed parameters.
With heat capacities Cc and Cs. presumed and a, /3, and y identified, Re, Rc, and Ru can be obtained by solving the following set of equations (equations (iv)):
fl (C, + CS) CSR + yCsRu + 1 = 0 Rc -- )61 CsCcRit Re = aCcC,Rc The equation for Ru in the equations (iv) can lead to two solutions, but the suitably correct solution can be decided based on coolant flow conditions.
The least squares algorithm in equations (i) can then be applied for parameter identification.
Adaptive Observer Design Referring again to figure 1, in this embodiment the adaptive observer 12 can perform on-line parameter and state estimation simultaneously. Here, the adaptive observer 12 is a closed loop observer. Closed loop observers, such as a Luenberger observer or a Kalman filter, can be designed to estimate unmeasurable states of a system based on a model and feedback of measurable outputs ik = AR + Bu + L(y ¨ ji) y = Cx + Du
Ru(v) _a_ ¨ 1 ReRc RcCc R D cCc A =[ 1 11, 0 =[cc 11, C = [0 1], D = 0 _ 0 ¨c, RcCs CsRc In this embodiment, the difference between the measured and the estimated output is used as the feedback in order to correct the estimated states.
Compared with an open loop observer (i.e., observer without output feedback), the closed loop observer can accelerate the convergence of the estimated states to those of the real plant under unknown initial conditions, e.g., a Luenberger observer, or optimize the estimation by balancing the effect of the process and measurement noises, e.g., a Kalman filter.
Though an open loop observer may be suitable in some embodiments, a closed loop observer may be preferred in others.
In the closed loop observer embodiment, the adaptive observer 12 is designed by taking the structure of a closed loop observer and based on certainty equivalence principle cct = 121-4, + s A. + li(T, ¨ i's) Kc = Tf ¨ i's Ts ¨ "Pc Cs Ds ¨ ,, 255) Ku Kc where D., and De are the estimated surface and core temperatures, and the observer parameters fie, fic, and fiu are taken from the online identification set forth above. In the embodiment of figure 1, in real time the input current I, coolant temperature Tr, and
The estimations for both parameters and temperatures are updated at each time step.
Parameterization of Battery Thermal Model with Temperature Dependent Re In the example of lithium-ion batteries, internal electrical resistance Re can vary and may depend on core temperature Te and state of charge (SOC). In general, internal resistance Re can be increased when temperatures are low and when the SOC is close to 0% or 100%. An Arrhenius function can be used to describe the relationship between internal resistance Re and core temperature Te as Re = Re,refexP(¨T T"f), where ReJef is the reference internal electrical resistance value at a certain reference temperature Tree, and Tref and Te are in K. Because, in the example of a vehicle, the change in internal resistance Re with respect to SOC is negligible under normal operating conditions (i.e., 20% to 80% SOC), the SOC is not considered in this embodiment. In other embodiments, the internal electrical resistance Re can be treated as a non-varying constant.
In order to address an internal resistance Re that varies with core temperature Te and suitably ensure avoidance of potential errors in previous estimations like the core temperature estimation, in this embodiment a least square algorithm with non-uniform forgetting factors is designed in order to identify Re as a time-varying parameter. In other embodiments, numerous methods could be employed to address a varying internal resistance; for example, the governing equations set forth above for the core temperature Te state and the surface temperature Ts state can be linearized around a certain operating point to a linear model, and equations (i) set forth above can be applied to identify all constant parameters of the linearized model.
In this embodiment, when forgetting factors are adopted, a least square algorithm will be
In general, the least square identification algorithm attempts to find optimal parameters that best fit the inputs and outputs over the whole data set. A
pure least square algorithm treats each data point as equal, no matter if it is acquired most recently, or obtained earlier. But when a forgetting factor is applied, the data points will be weighted differently. That is, the newly acquired data are favored over the older ones.
In the equation immediately above, the weight of the data will decay exponentially with the time elapsed, and the larger the forgetting factor is, the faster the decay will be.
Accordingly, the least square algorithm can track the parameters when they are time-varying.
The least square algorithm with forgetting factors can be applied to equation (ii) set forth above. Of the three lumped parameters in equation (ii)¨a, /3, and y¨only a is related to time varying Re, while all the others are constant. Therefore, non-uniform forgetting factors should be adopted in this embodiment with the n matrix designed as o oi n= [o o o where n, is the forgetting factor associated with a (and hence Re).
The recursive least square algorithm with forgetting factors can also track the long term growth of the internal electrical resistance Re, which can be used as an indication for and way to monitor the state of health (SOH) of the battery pack.
Different from the varying internal resistance Re caused by fluctuating core temperature Tc, the long term growth of the internal resistance Re is due to a degradation and/or aging process occurring slowly over the battery's lifetime. For instance, the internal resistance Re could increase appreciably over hundreds of cycles or days.
Figure 2A is a graph comparing simulated results (S) of internal electrical resistance growth, and identified (I) internal electrical resistance growth of the least
Scalable Battery Cluster Thermal Model and Sensor Deployment Analysis In a vehicle application example, battery cells are oftentimes packed in modules in order to be suitable for desired energy and power demands. A thermal model for a battery cluster is therefore designed, and can then be used to design a thermal observer for the battery cluster. The parameters identified by the parameter identifier 10 can be updated in real time to the cluster thermal model for adaptation. In one embodiment, in order to optimize temperature estimation, a closed loop observer with surface temperature Ts feedback is employed, which calls for observability.
Referring to figure 3, the governing equations set forth above for the core temperature Te state and the surface temperature Ts state can be scaled up to a cluster thermal model based on thermal energy transfer effects such as battery cell-to-cell heat conduction 24 and heat balance of flowing coolant 26 travelling from an inlet 28 of a battery pack 30 to an outlet 32. As shown in figure 3, the battery pack 30, or cluster, can be simplified by considering modules with battery cells 16 connected in series with tab structures 34 and geometrically arranged in rows along the coolant traveling path.
Coolant 22 flows through spaces between individual battery cells 16 from the inlet 28
The temperature evolution of the kth cell in a cluster can be modeled as (equations (v)) dT, k Ts,k Tc,k C = /2R, -1-c dt Rc dT, k = Tf k ¨ Ts,k Ts,k ¨ Tc k T, k_i + Ts,k+i ¨ 2Ts,k C
s dt Ri, Rc Rcc Ts,k-1 Tf,k-1 Tf,k = Tf,k-11-RuCf where k is the index of the battery cell along the coolant flow direction.
In equations (v), heat conduction between battery cells is modeled as heat flow over conduction resistance Rcc, driven by the temperature difference between adjacent battery cell surfaces 20. In this embodiment, conduction resistance 12,, is a lumped parameter and may include heat conduction through the tab structure 34 and through other possible connections between battery cells, depending on cluster and cell construction. Coolant flow temperature of the kth battery cell, Tf,k, can be determined by the flow heat balance of the previous battery cell, which can be calculated by ¨Tk¨1 dividing the heat removed Ts, Lk-1 from the k- 1 th battery cell by coolant flow Ru capacity Cf. Here, it is assumed that all the battery cells have the same parameters and that the current is the same for all of the battery cells since the battery cluster is in series connection.
In general, coolant flow temperature at the inlet 28 is greater than coolant flow temperature at the outlet 32, since the coolant will pick up heat from the battery cells
In the example vehicle application, because it is impractical to measure the surface temperature Ts for every single battery cell in the battery pack, model based temperature monitoring can be utilized since it can estimate the surface and core temperatures Ts, Tc for every single battery cell in the battery pack. The cluster thermal model, i.e., equations (v), can be employed for this purpose. In different embodiments, the model based temperature monitoring can be an open loop observer or a closed loop observer.
An open loop observer estimates states with the model based solely on input.
In this instance, the current and coolant inlet temperature Tf may be measured and applied to the equations (v) in order to calculate all of the temperatures in the battery pack. The open loop observer may give accurate state estimation if the initial conditions (i.e., temperatures) of all the temperature states are known, which may be the case when all the battery cells in the battery pack are at the coolant inlet temperature Ti. When the initial conditions are unknown or not available, the open loop observer state estimation will still converge to the real states gradually if the linear system is stable. The speed of convergence may be dictated by the system dynamics. A stable system here refers to systems whose states will all decay to zero subject to zero input.
In the example vehicle application, unknown initial conditions are not uncommon. Since temperature measurement sensors may be installed only on the battery cell surfaces 20, only the initial surface temperature can be obtained precisely at vehicle start-up operation while the initial core temperature remain unknown. If the vehicle and accompanying battery pack are started-up from steady states¨such as after an overnight rest¨the unmeasured and unknown initial core temperature of the battery cells can be assumed to be the same as the measured and known initial surface temperature. But this assumption may not be suitable for an abbreviated vehicle shutdown.
Furthermore, in the graph, Li represents the simulated real surface temperature of cell one, Ts5 represents the simulated real surface temperature of cell five, Tslestcl represents the estimated surface temperature of cell one using a closed loop observer, Ts5estcl represents the estimated surface temperature of cell five using a closed loop observer, Tslestot represents the estimated surface temperature of cell one using an open loop observer, and Ts5estol represents the estimated surface temperature of cell five using an open loop observer.
Similarly, figure 4B is a graph showing simulated results of convergence times of estimated core temperatures using a closed loop observer with real core temperatures, and of convergence times of estimated core temperatures using an open loop observer with real core temperatures. In the graph, core temperature Tc is plotted on the y-axis, and time is plotted on the x-axis. Again here, for illustrative and demonstrative purposes, the battery pack subject to simulation had five individual battery cells provided in series similar to the arrangement depicted in figures 5A, 5B, and only core temperatures of battery cell one ("Celli" in figures 5A, 5B) and cell five ("Ce115" in figures 5A, 5B) in the series are plotted in the graph. Furthermore, in the graph, I'd represents the simulated real core temperature of cell one, Tc5 represents the simulated real core temperature of cell five, Tclestcl represents the estimated core temperature of cell one using a closed loop observer, Tc5estcl represents the estimated core temperature of cell five using a closed loop observer, Tclestol represents the estimated core temperature of cell one using an open loop observer, and Toestot represents the estimated core temperature of cell five using an open loop observer. The simulation in figures 4A and 4B assume known parameters for all of the battery cells identified by the
In the simulation, the real initial surface and core temperatures of all the battery cells were set to be 30 C and 37 C, respectively. For the open loop observer, the initial core temperatures are assumed to be the same as the measured surface temperatures, which are 30 C. Figures 4A and 4B show that the settling time for open loop estimation of the surface and core temperatures for both cell one and cell five is greater than thirty minutes (denoted "Convergence of Toestd," "Convergence of To estd,"
"Convergence of Toestd," and "Convergence of Tc 1 estd" in figures 4A and 4B). While such a settling time may be suitable in some embodiments, it may not suitable in all embodiments.
Accordingly, in some embodiments, a closed loop observer can be employed for the model based temperature monitoring and may reduce the settling time compared to that of the open loop observer. In one embodiment, the closed loop observer may be designed as a Kalman filter, or could have another design. For the closed loop observer, some of the states (e.g., battery cell surface temperature) are measured and any errors between the measurement and the estimation are fed back to the model based observer in order to correct the estimation. Taking a battery cell string with two individual cells as an example, the closed loop observer takes the form of .5c.' = Al + Bu +
L(y ¨
,9 = Cl + Du, where the A matrix and x, u, and B are (equations (vi)) R,Cc R,Cc 1 _ _ (_ + ___ + ___) 0 A = RccCs RC R C R Cs 1 , R C c s u s cc 0 ( 1 1 RcCc ( __ + 1 1 1 1 _ ___ + _ RCf= Cs+ RccCs _ R C R
C R C) u s c s cc s _ 0 RcCs _ -Re 0 _ cc 1 0 X = [Tc,1 Ts,1 TC,2 TS,21T , U = [12 Ti]T RuCs , B = Re 0 Cc RuC r-1 -0 RaCsC f
Accordingly, the previously-known and, in some case required, procedures of accurately determining the initial temperatures of battery cells in a battery pack may be eliminated in some embodiments described herein.
As mentioned, figure 4B shows simulated results of convergence times of estimated core temperatures using a closed loop observer with real core temperatures, and of convergence times of estimated core temperatures using an open loop observer with real core temperatures. As shown in this simulation example, the closed loop observer converges much sooner than the open loop observer. Both temperatures estimated by the closed loop observer converge to the real temperatures within minutes.
In general, the effectiveness of a closed loop observer can be based on the observability of the battery pack model. The observability of a model can be examined by its observability matrix (equation (vii)) CA I
Q=
CA' where A is the system matrix and C is the output matrix as in the equation y =
Cx +
Du, and n is the order of the system. The model will be completely observable if the rank of Q is equal to n.
As an example, a battery string with two individual battery cells, whose A
matrix is specified under equations (vi), is looked at for simplicity. In the A
matrix equation, the ¨ terms in the second and fourth rows reflect the thermal interaction between the Rcccs
As another example, a battery string with three individual battery cells has an A
matrix IS A_3cell -¨ ¨Rccc 0 0 0 0 Rc cc 1 _ /1 1 1 '\ 1 0 ¨ 0 0 Rcc, R + +ccs Ruc, Rcccsi Rccc, = 1 1 -- Rccc 0 0 RcCc 1 1 2 Rccc, 0 Riicf cs Recc, 1 ¨ (¨ -I- ¨ + ¨
Ruc, Rcc, Rcccs) 1 0 0 --Rccc Rcc 0 ul s 1 \ cc, 0 1 Rc R2 C C (1¨ RuCf ) 0 RcCs ¨ (¨ 1 + ¨ +
¨
R 1 ,icfc,+¨ 1 Rccc, Rcc, Ruc, Rcccs)_ In this example, the ¨Rcics terms in the second, fourth, and sixth rows reflect the interaction between the adjacent battery cells via cell-to-cell conduction, and the --2--1 -RuC f Cs term in the fourth row accounts for the impact of the first battery cell on the second battery cell by coolant flow convection. Additional details concerning the battery cell interconnection via coolant convection can be revealed by looking at the sixth row of the A matrix. In the sixth row, the -7 1 --- term in the fourth column represents the RuC f Cs impact of the second battery cell on the third battery cell through coolant convection,
battery cell on the third battery cell. Indeed, all of the previous battery cells in the battery string may affect the subsequent battery cells through coolant flow convection, and the farther apart the two battery cells physically are, the weaker the effect may be.
The coolant convection effects are different than the cell-to-cell conduction effects, as the conduction effects may only exist between adjacently connected battery cells and the strength may always be the same.
Furthermore, for battery cell strings having any number of battery cells, once the particular A matrix is established, observability analysis can be performed in order to determine the minimum number of temperature sensors needed to provide full observability. Results are provided below in Table 1.
Number of Cells in the Minimum Number of Sensors String Suitable 1, 2, 3 1 4, 5, 6 2 7, 8, 9 3 10, 11, 12 4 Table 1 It has been determined that for battery cell strings with greater than five battery cells, the location of the temperature sensors on the surfaces of the cells has an effect on observability. For example, in a battery cell string with five battery cells, although the minimum number of temperature sensors to establish full observability is two sensors, different sensor locations among the battery cells may give different results concerning observability. This is demonstrated in figures 5A and 5B, where coolant flow travels from left to right and neighboring individual battery cells are connected to each other via a tab structure. When two temperature sensors are placed on the surfaces of battery cells one and two in the example battery cell string of figure 5A
(denoted
respectively), as shown, the Q matrix will be of full rank and may thus provide full observability.
In general, observability indicates the possibility of determining all the states based on the available measurements and the model. The model defines the relations between different states and therefore in order to achieve full observability, the measurements should be able to provide enough constraints to restrict the states to a single set of solution based on the model. In the example of figures 5A and 5B, when the temperature sensors are located on battery cells one and two (figure 5A), the constraints provided by the temperature sensors may be somewhat redundant at the beginning portion of the battery cell string since the surface temperature of battery cell two can be estimated based on the measured surface temperature of battery cell one and the model. Because there is no surface temperature measurement in the end portion of the battery cell string, the temperatures of the battery cells in that portion cannot suitably be constrained to unique values. Accordingly, full observability may not be suitably satisfied. In contrast, when the temperature sensors are located on battery cells one and five (figure 5B), constraints may be imposed on the battery cell string evenly, and therefore all the states can be determined by the surface temperature measurements and the model.
Furthermore, it has been determined that, in some cases, the thermal energy transfer effects among the battery cells may be weaker if either battery cell-to-cell heat conduction or coolant convection is absent or negligible. For instance, cell-to-cell heat conduction may be minor in some battery packs due to the shape and/or material of the accompanying tab structure. Also, when the coolant flow is not circulated through the battery pack¨such as when there is a battery thermal management system breakdown or fault¨the battery cells would then be cooled by way of natural convection and preceding battery cells may not effect subsequent battery cells via coolant convection.
In these circumstances, the observability conditions will be different. For example, taking the battery cell string of figures 5A and 5B, when coolant circulation is disabled and the battery cells are cooled by natural convection, and when two temperature
In an example, a battery cell string having twelve battery cells was analyzed in terms of observability. The results of that analysis are provided below in Table 2. For twelve battery cells, according to Table 1, the minimum number of temperature sensors to give full observability is four. Table 2 shows that, among all of the four-hundred-and-ninety-five possible combinations of locations among the battery cells of the four temperature sensors, when there is both circulated coolant convection and cell-to-cell heat conduction ("Full Cell Interconnection"), one-hundred-and-six combinations will give full observability. When there is natural convection with no coolant flow but still cell-to-cell heat conduction ("Natural Convection Effects"), fifty-two combinations will give full observability. And when cell-to-cell heat conduction is absent ("No Cell-to-Cell Conduction"), only one combination will give full observability¨that combination would be locating temperature sensors on the surfaces of battery cells three, six, nine, and twelve in the battery cell string.
Conditions Number of Combinations Providing Observability Full Cell Interconnection 106/495 Natural Convection Effects 52/495 No Cell-to-Cell Conduction 1/495 Table 2 Cell-to-cell heat conduction tends to have a greater effect on observability than coolant convection. One possible reason for this is that cell-to-cell heat conduction is a two-way thermal energy transfer effect¨that is, heat can be exchanged between both battery cells in both directions. Coolant convection, in contrast, may provide thermal energy transfer effects in a single direction. According to this, battery packs can be
It is to be understood that the invention is not limited to the particular embodiment(s) disclosed herein, but rather is defined solely by the claims below.
Furthermore, the statements contained in the foregoing description relate to particular embodiments and are not to be construed as limitations on the scope of the invention or on the definition of terms used in the claims, except where a term or phrase is expressly defined above. Various other embodiments and various changes and modifications to the disclosed embodiment(s) will become apparent to those skilled in the art.
All such other embodiments, changes, and modifications are intended to come within the scope of the appended claims.
As used in this specification and claims, the terms "for example," "for instance,"
and "such as," and the verbs "comprising," "having," "including," and their other verb forms, when used in conjunction with a listing of one or more components or other items, are each to be construed as open-ended, meaning that the listing is not to be considered as excluding other, additional components or items. Other terms are to be construed using their broadest reasonable meaning unless they are used in a context that requires a different interpretation.
Claims (16)
a) dynamically receiving a surface temperature of less than all of the battery cells in the battery pack, a current of the less than all battery cells, an inlet temperature of coolant provided to the battery pack, and a flow rate or velocity of the coolant;
b) dynamically estimating a cell-lumped internal electrical resistance of the less than all battery cells, a cell-lumped conduction resistance between a core and a surface of the less than all battery cells, and a cell-lumped convection resistance between the surface of the less than all battery cells and the coolant, the estimations based upon the received values of step a);
c) dynamically estimating a core temperature and a surface temperature of the less than all battery cells based upon the received values of step a) and based upon the estimated values of step b);
d) using thermal energy transfer effects between the coolant and the battery cells, thermal energy transfer effects among the battery cells, and the estimated core temperature values of step c), in order to estimate the core temperatures for all of the battery cells in the battery pack; and e) comparing the received surface temperature values of step a) and the estimated surface temperature values of step c) in order to correct the estimation of the core temperatures of all of the battery cells in the battery pack.
The method of claim 1 wherein step b) further comprises dynamically estimating a heat capacity of the core of the less than all battery cells, and a heat capacity of the surface of the less than all battery cells, the estimations based upon the received values of step a).
a) dynamically receiving a surface temperature of at least one battery cell in the battery pack, a current of the at least one battery cell, an inlet temperature of coolant provided to the battery pack, and a flow rate or velocity of the coolant;
b) dynamically estimating a cell-lumped internal electrical resistance of the at least one battery cell, a cell-lumped conduction resistance between a core and a surface of the at least one battery cell, and a cell-lumped convection resistance between the surface of the at least one battery cell and the coolant, the estimations based upon the received values of step a);
c) dynamically estimating a core temperature of the at least one battery cell and a surface temperature of the at least one battery cell, based upon the received values of step a) and based upon the estimated values of step b); and d) comparing the received surface temperature values of step a) and the estimated surface temperature values of step c) in order to correct the estimation of the core and surface temperatures of the at least one battery cell of step c).
at least one sensor coupled to at least one battery cell of the battery pack in order to measure a surface temperature of the at least one battery cell;
a controller coupled to the at least one sensor in order to receive the measured surface temperature, wherein the controller performs the steps of:
i) receiving a current of the at least one battery cell, an inlet temperature of coolant provided to the battery pack, and a flow rate or velocity of the coolant;
ii) estimating a cell-lumped internal electrical resistance of the at least one battery cell, a cell-lumped conduction resistance between a core and a surface of the at least one battery cell, and a cell-lumped convection resistance between the surface of the at least one battery cell and the coolant, the estimations based upon the measured surface temperature and the received values of step i);
iii) estimating a core temperature of the at least one battery cell based upon the measured surface temperature, the received values of step i), and the estimated values of step ii); and iv) using thermal energy transfer effects between the coolant and the battery cells, thermal energy transfer effects among the battery cells, and the estimated core temperature values of step iii), in order to estimate the core temperatures for all of the battery cells in the battery pack;
v) estimating a surface temperature of the at least one battery cell and comparing the measured surface temperature and the estimated surface temperature in order to correct the estimation of the core temperature for all of the battery cells in the battery pack; and a battery thermal management assembly coupled to the controller and controlled by the controller based upon the estimated core temperatures for all of the battery cells in the battery pack.
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| PCT/US2013/042496 WO2013177442A1 (en) | 2012-05-23 | 2013-05-23 | Estimating core temperatures of battery cells in a battery pack |
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Families Citing this family (43)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| FR2980307B1 (en) * | 2011-09-15 | 2014-11-07 | Renault Sa | METHOD FOR ESTIMATING THE HEART TEMPERATURE OF A BATTERY CELL |
| DE102011121454A1 (en) * | 2011-12-16 | 2013-06-20 | Audi Ag | Control device for a motor vehicle, motor vehicle and method for configuring the control device |
| US9381825B2 (en) | 2014-02-20 | 2016-07-05 | Ford Global Technologies, Llc | State of charge quality based cell balancing control |
| US9539912B2 (en) * | 2014-02-20 | 2017-01-10 | Ford Global Technologies, Llc | Battery capacity estimation using state of charge initialization-on-the-fly concept |
| US10059222B2 (en) * | 2014-04-15 | 2018-08-28 | Ford Global Technologies, Llc | Battery temperature estimation system |
| US9318778B2 (en) * | 2014-09-17 | 2016-04-19 | GM Global Technology Operations LLC | Systems and methods for battery system temperature estimation |
| KR101628489B1 (en) * | 2014-09-25 | 2016-06-08 | 현대자동차주식회사 | Apparatus and method for controlling high voltage battery in vehicle |
| US20170033572A1 (en) * | 2015-07-27 | 2017-02-02 | Robert Bosch Gmbh | Capacity estimation in a secondary battery |
| JP6274166B2 (en) * | 2015-08-06 | 2018-02-07 | 株式会社デンソー | Battery temperature estimation device |
| KR102527334B1 (en) * | 2015-11-24 | 2023-05-02 | 삼성전자주식회사 | Method and apparatus for battery management |
| US10224579B2 (en) | 2015-12-31 | 2019-03-05 | Robert Bosch Gmbh | Evaluating capacity fade in dual insertion batteries using potential and temperature measurements |
| KR102574083B1 (en) | 2016-01-12 | 2023-09-04 | 삼성전자주식회사 | Apparatus and method for managing battery |
| US10686321B2 (en) | 2016-01-29 | 2020-06-16 | Robert Bosch Gmbh | Secondary battery management |
| US10263447B2 (en) | 2016-01-29 | 2019-04-16 | Robert Bosch Gmbh | Secondary battery management system |
| US10243385B2 (en) | 2016-01-29 | 2019-03-26 | Robert Bosch Gmbh | Secondary battery management system |
| US10354026B2 (en) * | 2016-02-16 | 2019-07-16 | Dassault Systemes Simulia Corp. | System and method for the generation and use of an electro-thermal battery model |
| US10569660B2 (en) | 2016-02-26 | 2020-02-25 | Ford Global Technologies, Llc | Systems and methods for battery state-of-health monitoring |
| US9960625B2 (en) | 2016-03-31 | 2018-05-01 | Robert Bosch Gmbh | Battery management system with multiple observers |
| US10447046B2 (en) | 2016-09-22 | 2019-10-15 | Robert Bosch Gmbh | Secondary battery management system with remote parameter estimation |
| US20220187139A1 (en) * | 2019-03-19 | 2022-06-16 | Gs Yuasa International Ltd. | Estimation device and estimation method |
| CN114051671A (en) * | 2019-08-30 | 2022-02-15 | 株式会社杰士汤浅国际 | Estimation device and estimation method |
| DE102019125237A1 (en) * | 2019-09-19 | 2021-03-25 | Audi Ag | Method for determining a temperature distribution along a battery, observation device and battery |
| CN112578298B (en) * | 2019-09-29 | 2022-03-15 | 比亚迪股份有限公司 | Battery temperature estimation method, device, electronic equipment and storage medium |
| CN110823410B (en) * | 2019-11-21 | 2020-09-22 | 北京理工大学 | Method and system for determining core temperature of battery |
| US11566948B2 (en) * | 2020-02-13 | 2023-01-31 | Honeywell International Inc. | Enhancing RTD measurement accuracy by means of variable excitation current |
| DE102020113829B3 (en) * | 2020-05-22 | 2021-09-30 | Einhell Germany Ag | Core temperature in a cylindrical energy store |
| GB2595496B (en) * | 2020-05-28 | 2024-05-08 | Jaguar Land Rover Ltd | System and method for determination of battery temperature |
| US11215667B1 (en) * | 2020-06-24 | 2022-01-04 | Total S.A. | Interval estimation for state-of-charge and temperature in battery packs with heterogeneous cells |
| WO2022055619A1 (en) * | 2020-09-08 | 2022-03-17 | Analog Devices, Inc. | Technique for estimation of internal battery temperature |
| CN112798971B (en) * | 2020-12-30 | 2022-08-02 | 浙大城市学院 | Soft-package type lithium ion battery coupling electric thermal model |
| CN115128465A (en) * | 2021-03-29 | 2022-09-30 | 恒大新能源技术(深圳)有限公司 | Battery thermal simulation system and method and electronic equipment |
| US20220344734A1 (en) * | 2021-04-14 | 2022-10-27 | Analog Devices, Inc. | Technique for estimation of internal battery temperature |
| KR102852578B1 (en) * | 2021-04-27 | 2025-08-28 | 주식회사 엘지에너지솔루션 | Heating value measuring device |
| CN113459839B (en) * | 2021-07-23 | 2023-04-25 | 吉林省中赢高科技有限公司 | Method and device for temperature compensation based on DC charging stand |
| US12420673B2 (en) | 2022-02-03 | 2025-09-23 | Ford Global Technologies, Llc | Temperature based control of vehicle battery |
| CN114899523B (en) * | 2022-05-18 | 2023-05-02 | 浙江大学 | Lithium ion battery monomer thermal runaway core temperature estimation method |
| DE102022206808A1 (en) * | 2022-07-04 | 2024-01-04 | Robert Bosch Gesellschaft mit beschränkter Haftung | Method for operating a cell system with at least one electrochemical cell, a cell system and a computer program |
| CN115291115B (en) * | 2022-08-30 | 2024-06-04 | 北京航空航天大学 | Liquid cooling battery module core temperature online estimation method |
| CN117949824B (en) * | 2022-10-31 | 2025-09-09 | 比亚迪股份有限公司 | Battery health state prediction method, electronic equipment and readable storage medium |
| US12522105B2 (en) | 2023-04-21 | 2026-01-13 | Garrett Transportation I Inc. | Battery thermal controls for batteries used in electric vehicles and power wall applications |
| EP4550521A3 (en) * | 2023-11-03 | 2025-05-21 | Tata Consultancy Services Limited | Method and system of predicting temperature distribution in a battery pack |
| US12613286B2 (en) | 2024-01-22 | 2026-04-28 | Garrett Transportation I Inc. | System and method for battery parameter recharacterization |
| CN118731723B (en) * | 2024-09-02 | 2025-01-10 | 宁德时代新能源科技股份有限公司 | Battery pack damage assessment method, device, vehicle, equipment and storage medium |
Family Cites Families (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US5711605A (en) | 1996-03-12 | 1998-01-27 | Globe-Union, Inc. | Method and apparatus for predicting battery temperature |
| US6076964A (en) | 1998-11-11 | 2000-06-20 | Chrysler Corporation | Prediction of internal temperature of a battery using a non-linear dynamic model |
| JP3832332B2 (en) | 2001-12-20 | 2006-10-11 | 日産自動車株式会社 | Battery temperature detector |
| US7514904B2 (en) * | 2005-12-20 | 2009-04-07 | Caterpillar Inc. | System and method for determining battery temperature |
| US8936394B2 (en) * | 2010-05-25 | 2015-01-20 | GM Global Technology Operations LLC | Real-time estimation of cell core temperature during period of rest |
| US8529125B2 (en) * | 2010-05-26 | 2013-09-10 | GM Global Technology Operations LLC | Dynamic estimation of cell core temperature by simple external measurements |
| US8775105B2 (en) * | 2010-10-28 | 2014-07-08 | GM Global Technology Operations LLC | Onboard adaptive battery core temperature estimation |
-
2013
- 2013-05-23 WO PCT/US2013/042496 patent/WO2013177442A1/en not_active Ceased
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