CA3169651C - Real-time battery fault detection and state-of-health monitoring - Google Patents
Real-time battery fault detection and state-of-health monitoring Download PDFInfo
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- 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]
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- 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
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- 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]
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- 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]
- G01R31/382—Arrangements for monitoring battery or accumulator variables, e.g. SoC
- G01R31/3842—Arrangements for monitoring battery or accumulator variables, e.g. SoC combining voltage and current measurements
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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
- H01M10/05—Accumulators with non-aqueous electrolyte
- H01M10/052—Li-accumulators
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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
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—ELECTRIC POWER NETWORKS; CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or discharging batteries or for supplying loads from batteries
- H02J7/80—Circuit arrangements for charging or discharging batteries or for supplying loads from batteries including monitoring or indicating arrangements
- H02J7/82—Control of state of charge [SOC]
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—ELECTRIC POWER NETWORKS; CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or discharging batteries or for supplying loads from batteries
- H02J7/80—Circuit arrangements for charging or discharging batteries or for supplying loads from batteries including monitoring or indicating arrangements
- H02J7/84—Control of state of health [SOH]
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—ELECTRIC POWER NETWORKS; CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or discharging batteries or for supplying loads from batteries
- H02J7/90—Regulation of charging or discharging current or voltage
- H02J7/92—Regulation of charging or discharging current or voltage with prioritisation of loads or sources
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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]
- G01R31/374—Arrangements for testing, measuring or monitoring the electrical condition of accumulators or electric batteries, e.g. capacity or state of charge [SoC] with means for correcting the measurement for temperature or ageing
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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
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- 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
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Abstract
Description
[0001]
TECHNICAL FIELD
BACKGROUND
Accordingly, it may be desirable to monitor battery performance and detect conditions that may indicate problems, so that the battery can be serviced or replaced before it fails.
Date Recue/Date Received 2022-08-04 SUMMARY
The prediction can be compared to the actual behavior of the cell (e.g., a measured potential of the cell) to determine whether a potential problem, referred to herein as a "model fault"
condition, exists.
As another example, a battery monitoring system can maintain an estimate of battery state-of-health parameters such as charge capacity and internal resistance; these estimates can be updated in real time while the battery is being discharged and/or charged, and anomalous variations in the state-of-health parameters can indicate a "suspicious parameter" fault. The battery monitoring system can provide notifications of detected faults in real time, allowing prompt corrective action to be taken.
computing an unfiltered charge capacity value using the initial state of charge, the final state of charge, and the total amount of charge transferred; and updating a charge capacity estimate using the unfiltered charge capacity value.
measuring a final cell potential and a final cell temperature of the battery cell when the battery cell returns to the idle state; and computing a state of charge for the battery cell based on the equivalent cell circuit model using the final cell potential and the final cell temperature.
In the event that one or more of the measured potential, current, or temperature is not within the predefined valid ranges, the method can include waiting for the next time step without updating the running estimate.
measuring values of a plurality of operating-state parameters of the battery cell (e.g., current through the battery cell, temperature of the battery cell), including measuring an actual potential of the battery cell; computing an optimistic potential based on a cell state model (e.g., an equivalent cell circuit model), the measured values of a first subset of the operating-state parameters, and optimistic values for the one or more state-of-health parameters, the optimistic values corresponding to a better state of health than the current values of the one or more state-of-health parameters; computing a pessimistic potential based on the cell state model, the measured values of the first subset of operating-state parameters, and pessimistic values for the one or more state-of-health parameters, the pessimistic values corresponding to a worse state of health than the current values of the one or more state-of-health parameters;
determining whether the actual potential of the battery cell is substantially within an envelope defined by the optimistic potential and the pessimistic potential; and generating a model fault notification in the event that the actual potential is not substantially within the envelope. In various embodiments, the method can be performed in real time while the battery cell is powering a load and/or while the battery cell is charging. Model fault notifications can be generated in real time while the battery is in active use (powering a load and/or charging). In some embodiments, a predicted potential of the battery cell can also be computed based on a cell state model, the measured values of a first subset of the operating-state parameters, and the current values of the one or more state-of-health parameters.
[0017a] Accordingly, there is described a method for monitoring charge capacity of a battery cell, the method comprising: while the battery cell is in an idle state, determining an initial state of charge of the battery cell; thereafter monitoring a total amount of charge transferred from or to the battery cell while the battery cell is an active state; after the battery cell returns to the idle state, determining a final state of charge of the battery cell;
computing an unfiltered charge capacity value using the initial state of charge, the final state of charge, and the total amount of charge transferred; and updating a charge capacity estimate using the unfiltered charge capacity value.
[0017b] There is also described a battery monitoring system comprising: a battery interface to receive sensor data from a battery sensor of a battery cell; a control system interface to provide output data to a control system; a memory; and a processor coupled to the memory, the battery interface, and the control system, the processor configured to:
determine, while the battery cell is in an idle state, an initial state of charge of the battery cell; thereafter monitor a total amount of charge transferred from or to the battery cell while the battery cell is an active state; determine, after the battery cell returns to the idle state, a final state of charge of the battery cell; compute an unfiltered charge capacity value using the initial state of charge, the final state of charge, and the total amount of charge transferred; and update a charge capacity estimate stored in the memory using the unfiltered charge capacity value.
[0017c] There is also described a computer-readable storage medium having stored therein program instructions that, when executed by a processor in a battery monitoring system coupled to a battery cell, cause the processor to execute a method comprising:
while the battery cell is in an idle state, determining an initial state of charge of the battery cell;
thereafter monitoring a total amount of charge transferred from or to the battery cell while the battery cell is an active state; after the battery cell returns to the idle state, determining a final state of charge of the battery cell; computing an unfiltered charge capacity value using the Date Recue/Date Received 2023-01-06 initial state of charge, the final state of charge, and the total amount of charge transferred; and updating a charge capacity estimate using the unfiltered charge capacity value.
BRIEF DESCRIPTION OF THE DRAWINGS
5a Date Recue/Date Received 2023-06-16 DETAILED DESCRIPTION
System Overview
Battery 102 can be any type of battery, including a lithium ion battery, lead-acid battery, nickel-metal-hydride battery, and so on. Battery 102 can be implemented as a single battery cell or as a battery pack that includes multiple battery cells connected together in series and/or in parallel as desired. (As used herein, the term "battery cell" or "cell" can be understood as including a standalone battery or, in the case of a battery pack, one of some number of independently replaceable battery units within the battery pack.) Electrical load 104 can include, for example, a motor (or engine) of the vehicle, or any other battery-powered mechanism or device. Eleo,tical load 104 can draw varying amounts of power from battery 102 at different times. For example, a motor of a vehicle may draw more power when the vehicle is accelerating than when the vehicle is at rest or moving at a constant speed.
Charger 110 can include any system or device that is capable of providing power (or charge) from an external source (e.g., standard wall power or any other power source external to battery 102) to be stored by battery 102; numerous examples are known in the art. Charger 110 can also include control circuitry to control the operation of charger 110, including when and how much power to supply. In some embodiments, battery 102 can be coupled to charger 110 at certain times and decoupled from charger 110 at other times; hence, charger 110 is shown using broken lines. Depending on implementation, battery 102 may or may not be able to provide power to load 104 while receiving power from charger 110. In some embodiments, control system 106 can coordinate the operation of charger 110 with load-powering operation of battery 102.
notifications indicating that some aspect of battery performance has deviated from expectations, and/or any other information that may be available in battery monitoring system 108. Control system 106 and/or charger 110 can use this information to generate alerts to an operator of environment 100, to change the operation of load 104 based on the battery status information, to change the operation of charger 110 (e.g., the rate at which charging power is supplied to battery 102) based on the battery status information, to maintain battery history information for battery 102, and/or to take other responsive action that may be programmed into control system 106.
In this example, battery 102 can be coupled to charger 110 for recharging between flights, and battery monitoring system 108 can continue to provide information about the status of each battery pack during charging.
The number of cells 212 can be quite large. In this example, battery cells 212 within each HV battery 210a-b are connected in series to form strings having a large number of cells 212 (e.g., 144 cells per string), and three series strings are connected together in parallel within each HV battery 210a-b. Battery bank 200 can provide both a high operating voltage (e.g., overall system voltage in a range from about 400 to 800 V) and a high level of redundancy, such that battery bank 200 can continue to supply power even if some of cells 212 fail.
board 220 can be a printed circuit board with circuitry configured to monitor the status of one or more cells within the HV battery 210. In some embodiments, BMS boards 220 are capable of monitoring every cell of each HV battery 210. For instance, each HV battery 210 can include 12 BMS boards 220, with each BMS board capable of monitoring 36 cells.
Examples of components and operations that can be implemented in BMS boards 220 are described below.
battery system can include any number of batteries, and each battery can include any number of cells Battery monitoring as described herein can be performed at the level of individual cells, or a group of cells can be monitored as a unit if desired.
For instance, the cell state model can predict the state of charge and state of polarization (or voltage) of a cell at a given time step based on the current drawn, temperature, internal resistance, charge capacity, and state of charge at a previous time step. In some embodiments, the same cell state model is applied to all cells, but predictions for different cells may differ due to differences between cells with respect to configuration and/or state parameter values. As another example, a cell state model can be used to estimate cell configuration parameters that may evolve over time, such as charge capacity and internal resistance.
Specific examples are described below.
In examples described herein, battery monitoring is performed for a cell;
however, battery monitoring at a higher level (e.g., a group of serially connected cells or an entire battery pack or battery bank) is not precluded. Battery monitoring system 300 can implement any number and combination of monitoring operations, including but not limited to any one or more of the examples described below. In some embodiments, a battery monitoring system can also support other battery management operations such as calibration, self-testing, and so on.
Model Fault Detection
The cell state can be defined and monitored using the variables defined in Table 1, where subscript k denotes a time step.
Variable Definition (units) Vpred,k Predicted cell potential (volts (V)) Vactual,k (Or Vk) Measured cell potential (V) VP Cell polarization (V) Co Cell maximum charge capacity (ampere hours (Ah)) ¨
configuration parameter SOCk Cell state of charge (fraction of Co) Uk Maximum energy cell can discharge from present SOC at reference temperature Tref Qdischarge,k Amount of charge transferred as of time step k Sign convention can be used, e.g., Qdrscharge,k > 0 indicates discharging; n .clischarge,k < 0 indicates charging.
Ik Measured cell current (A) (Ik> 0 for discharging; IX < 0 for charging) Ri Cell internal resistance (ohms) ¨ configuration parameter Tk Measured cell temperature ( C) Pc Notational convenience indicating a cell state defined by [ Vp, SOCk dt Time step (seconds)
(1) The modelUpdate() function calculates the cell's SOC and predicted potential for time step k based on the previous cell state, measured current and temperature, estimated values of charge capacity Co and internal resistance A, and time step. The modelUpdate() function can be based on conventional models of cell behavior using an equivalent cell circuit model.
Examples of such models are known in the art, and an appropriate model can be selected based on the particular type of cell.
[0048] The time step dt may be chosen based on the current operating state of the cell. For example, the cell can have finite state model that includes the following states:
"Discharging" (current is being drawn from the battery); "Charging" (current is being applied .. to recharge the battery); "Relaxing" (current out of (or into) the battery is below a threshold indicating inactivity); and "Idle" (entered from the Relaxing state when the current remains below the inactivity threshold and the voltage remains stable over an extended period of time, e.g., at least 15 minutes). In some embodiments, process 400 can update the battery state at a higher rate (e.g., dt 1 s) when in the Discharging, Charging, or Relaxing state and at a lower rate (e.g., dt ¨ 900 s) when in the Idle state. Other state models can also be used.
.. [0050] Process 400 can begin with initialization at block 402.
Initialization can occur, for instance, when the battery management system is powered on or reset, or when the battery transitions from Idle state to any other state. Initialization can include establishing initial values of various parameters of a cell state model, on the assumption that the cell is not in use when initialization occurs. For example, Vp can be initialized to zero. Co and R can be initialized based on the last measured or estimated values. SOCo can be initialized to the last estimated SOC, or, if the battery is not polarized during initialization, SOCo can be calculated from measurements of Vactuai,o and To using a getS0C(V, T) function that computes cell state of charge as a function of cell potential and temperature based on an equivalent cell circuit model. In some embodiments, getS0C() can be computed in advance for a discrete set of potential and temperature values and stored in a lookup table to facilitate real-time computation. Other parameters and flags can also be initialized. For instance Qdischarge,o can be initialized to 0.
[0051] At block 404, for each iteration of process 400 (at time step k), new values of state parameters for the cell are determined. In some embodiments, determining new state parameters can include measuring the current being drawn (/k), the actual potential across the .. cell (Vaanar,k), and cell temperature (Tx) and applying Eq. (1) to determine SOCk and predicted potentials Vp and Vpred,k.
[0052] In some embodiments, determining new state parameters can also include estimating cell energy (Uk) and cell discharge Qdischarge,k. For example, the following equations can be used:
Ck (2) Uk = g et0 CV (¨ 'Tref) dC
Jo Co Qdischarge,k = Qdischarge,k-1+ Ikdt , (3) .. where getOCV(SOC, 7) in Eq. (2) is a function complementary to getS0C(V, 1) that computes cell potential (specifically the open circuit voltage) as a function of SOC and cell temperature based on an equivalent cell circuit model. Similarly to the getS0C() function, getOCV() can be computed in advance for a discrete set of SOC and temperature values and stored in a lookup table to facilitate real-time computation. It should be understood that Uk can be computed at each iteration, approximating the integral as a series of time steps.
[0053] At block 406, the state parameters determined at block 404 are used to compute a set of "optimistic" cell parameters and a set of "pessimistic" cell parameters, in particular an optimistic cell potential (Vopt) and a pessimistic cell potential (Vpess). The optimistic cell parameters represent state parameters for a hypothetical cell with increased charge capacity and decreased internal resistance (relative to the current estimates of Co and Re) that undergoes the same charge or discharge event as the cell being modeled.
Conversely, the pessimistic cell parameters represent state parameters for a hypothetical cell with decreased charge capacity and increased internal resistance (again, relative to the current estimates of Co and Ri) that undergoes the same charge or discharge event as the cell being modeled. In some embodiments, the optimistic and pessimistic cell parameters are not defined as a fixed error margin around the state parameters determined at block 404; instead they are computed dynamically using a cell state model.
[0054] By way of illustration, in some embodiments, an optimistic cell potential Vopt is defined on the following assumptions: the cell's maximum charge capacity Co is underestimated by an amount Kco,opt; the cell's internal resistance R, is overestimated by an amount KR,,opt; and the cell's overpotential is off by a scaling factor of1C7hopt. On this assumption, the following computations can be used to determine Vopt:
CO,opt = CO + KCO,opt A
(4) Cinit,opt = C0,0pt S000 , (5) Copt,k = Ctinit,opt Qdischarge,k (6) Copt,k (7) SO Copt* = , L'0,opt ec,opt = Kn,opt(Vc Ve) P
(8) Ri,opt,k = (Ri KRopt)exP (¨ERo(Tk Tref)) (9) Vopt* = getOCV(SOCopt,k, Tk) ¨ n ec,opt I kRi,opt,k P
(10) where ER0 is the activation energy. The K factors can be chosen as desired, e.g., based on empirical observations of cell-to-cell variability from design specifications for well-behaved cells. In some embodiments for a battery bank of the kind described above with reference to FIG. 2, Ka ,opt 0.1 Ah (e.g., 0.2 Ah), KRIppt ¨ 0.0001 SI (e.g., 0.0003 SA and Krhopt ¨ 0.7 (e.g., 0.75).
[0055] Similarly, in some embodiments, a pessimistic cell potential Vpess is defined on the following assumptions: the cell's maximum charge capacity Co is overestimated by an amount Kco,pess; the cell's internal resistance R, is underestimated by an amount KRipess; and the cell's overpotential is off by a scaling factor of Kibpess. On this assumption, the following computations can be used to determine Vpacs:
CA 03169651 2022-.07-29 CF =
/ > 0 (11) (Kchargeo I < 0 CO,pess = CO + KCO,pess =
(12) Cinit,pess = Comees S000 , (13) Cpess,k = Cinit,pess Qdtscharge,k (14) Cpess,k (15) C SO = , pess,k 1-'0,pess nec,pess = Kn,pess(Vc + Ve) p (16) Rimeee = (Ri + Krumeõ) exp (¨ER (Tk ¨ Tref)) , (17) Vpess,k = get0 CV (S 0Cpess,IcATk) CF * (n ec,pess I kRi,pess,k) =
(18) Similarly to the optimistic cell, the K factors for the pessimistic cell can be chosen as desired, based on empirical observations of cell parameters (and variability thereof) and/or based on specific changes that would indicate an electrical failure. In some embodiments for a battery bank of the kind described above with reference to FIG. 2, Kco,pess ¨0.1 Ah (e.g., 0.2 Ah), KRipess ¨ 0.0003 Z (e.g., 0.0001 S1)and K7hpess ¨ 0.7 (e.g., 035). In Eqs.
(11) and (18), CF is a scaling factor that is applied to the total overpotential of the cell when the cell is charging, accounting for increased variability in cell potential while charging. (As will become apparent, applying a scaling factor only to the pessimistic potential estimate ¨ or only to the optimistic potential estimate ¨ has the effect of widening an envelope of acceptable potentials when the cell is charging.) 100561 It should be noted that the labels "optimistic" and "pessimistic" are not intended to imply that Vopt,k > Vpess,k, and this need not be the case. For instance, Eqs.
(4)¨(10) and (11)¨
(18) yield the result that Vopt,k > Vpess,k when the cell is discharging, but when the cell is charging, Vpess,k > Vopt,k. In some embodiments, to ensure that the envelope has at least a minimum width, a padding potential Vpad can be used to fine-tune Vopt,k and Vpess,k. For example, if Vopt,k > Vpess,k, then the following equations can be used for fine-tuning:
Vapt,k = Vaptj, + Vpaa , (19) Vpess,k = Vpess,k Vpad =
(20) Similarly, if V pess,k > Vopt,k, then the following equations can be used for fine-tuning:
Vopt,k = Vopt,k Vpad (21) Vpess,k = Vpess,k Vpad =
(22) Vpad can be selected as desired, e.g., Vpad = 0.01 V.
[0057] At block 408, the optimistic parameters and pessimistic parameters are used to define an envelope of acceptable battery performance, such as an acceptable range of potentials. For instance, if Vopt,k > Vpess,k, the envelope can be defined as:
V > V > V
(23) opt,k ¨ k ¨ pess,k and if Vpess,k Vopt,k, the envelope can be defined as Vpess,k Vk Vopt,k (24) where Vk is the cell potential at time step k.
[0058] At block 410, the actual potential Vactuakk across the cell is measured. In some embodiments, the measurement can be made as part of determining state parameters of the cell at block 404.
[0059] At block 412, it can be determined whether the measured potential Vactual,k is within the envelope of acceptable battery performance, e.g., using either Eq. (23) or Eq. (24) as appropriate. In some embodiments, additional conditions may be applied. For example, the equivalent cell circuit model used to define the envelope may become unreliable if the cell SOCk is below a threshold (e.g., 0.1) or if the current Ik is in excess of a threshold (e.g., 70 A
for one type of cell). In conditions where the cell state model is unreliable, the envelope defined by the cell state model can be ignored (e.g., measured Vactual,k can be treated as always being within the envelope).
[0060] A measured potential Vactual,k that is outside the envelope may be indicative of a problem with the cell, and a model fault notification can be generated. In some embodiments, any instance of measured potential Vactual,k being outside the envelope can result in generating a model fault notification. In other embodiments, transient excursions outside the envelope are ignored as insubstantial fluctuations; a fault counter can be used to determine when an excursion outside the envelope is considered to be substantially outside the envelope. Accordingly, at block 414, if the measured potential is not within the envelope, a fault counter can be incremented; at block 416, if the measured potential is within the envelope, the fault counter can be reset. At block 418, it is determined whether the fault counter has exceeded a threshold, and if so, a model fault notification is generated at block 420. In some embodiments, generating the model fault notification in a battery management system such as battery management system 108 of FIG. 1 can include sending the notification to control system 106 (and/or other system components as desired). In various embodiments, a model fault notification can include other actions, such as illuminating an on-battery fault indicator light, sending a message to a maintenance service to request servicing of the battery at the next opportunity, and so on.
[0061] The counter threshold for generating a model fault notification can be a constant that is defined based on tradeoffs between sensitivity (ability to detect problems) and specificity (avoiding generation of fault notifications in the absence of a real problem). In one example, the determination whether the actual cell potential is within the envelope is performed at a rate of 1 Hz and the threshold for the fault counter is set at 30, so that a model fault event is generated if the actual potential remains outside the envelope for 30 seconds or longer. Other thresholds can also be chosen.
[0062] To further illustrate the operation of process 400, FIG. 5 shows example plots of cell potential as a function of time for a battery cell used to power an aircraft according to some embodiments. In this example, the aircraft is idle until shortly before time 1000 s, at which time the aircraft ascends to a cruising altitude and begins to cruise.
Shortly before time 3000 s, the aircraft descends. Solid line 502 corresponds to measured cell potential Vactual,k, Line 504 corresponds to the predicted potential Vpred,k predicted using a cell state model applied to actual cell parameters. (In this example, line 504 closely tracks the measured potential.) [0063] Line 506 corresponds to a predicted potential Vopt,k predicted using optimistic cell parameters as described above (with the same cell state model as line 504), and line 508 corresponds to a predicted potential Vpess,k predicted using pessimistic cell parameters as described above (again with the same cell state model as line 504). As can be seen, the width of the envelope defined by lines 506, 508 varies as a function of time. The width is affected by current cell behavior (e.g., how much current is being drawn) as well as hysteresis. In this example, the actual potential (line 502) remains within the envelope defined by lines 506, 508 or the duration measured, so no model fault event would be generated.
[0064] It will be appreciated that process 400 is illustrative and that variations and modifications are possible. To the extent that logic permits, operations described as sequential can be executed in parallel, or operations can be executed in a different order.
Other operations not specifically described can be performed, and operations specifically described can be omitted if desired. The cell state model and other parameter values (e.g., parameters for determining optimistic and pessimistic potentials) can be optimized for a particular implementation based on the type and properties of the battery cell and on the particular sensitivity and specificity desired. The monitoring process can be performed for any number of cells in parallel or sequentially. Monitoring using process 400 or similar processes can be performed while the battery is in any state Alternatively, if desired, monitoring can be performed only while in certain states (e.g., only during discharge events or only during charge events).
Cell State of Health Estimation [0065] As described above, model fault detection relates to detecting anomalous behavior of a battery or cell during active use. Apart from any anomalies, overall performance of a battery or battery cell (particularly a rechargeable battery or cell) can be expected to degrade slowly over time due to electrochemistry and thermodynamics, until the battery or cell reaches a point of uselessness. Accordingly, in addition to or instead of detecting anomalous behavior, some embodiments of a battery monitoring system can also monitor the "state of health" of a battery or individual cells of a multi-cell battery. In examples herein, state of health is characterized by the maximum charge capacity Co of the cell and the internal resistance Ri of the cell. As a cell degrades, maximum charge capacity tends to decrease while internal resistance tends to increase. In other embodiments, other parameters may be associated with state of health, in addition to or instead of Co and R1.
[0066] In some systems, monitoring of Co and Ri can be part of an active testing process that is performed while the battery is otherwise idle and connected to a charger or a load.
Examples of such active testing processes are known in the art. However, active testing processes typically require that the battery remain idle and connected to the charger or load for an extended period of time (which can be several hours). For batteries operating at a high duty cycle, an alternative process may be preferred.
100671 Accordingly, some embodiments of a battery monitoring system can use a "passive"
process to monitor Co and RI of a cell. The passive process relies on real-time monitoring of voltage, current, and temperature (the same state parameters that are measured during model fault detection processes described above), and Co and Ri can be quantitatively estimated from the measured parameters. In some embodiments, estimating Co and Ri can also include using a filtering function (e.g., a moving average) to smooth out fluctuations in the estimate.
The process is referred to as "passive" because it can be performed while the battery is in use, without affecting performance of the battery. Examples of passive processes for estimating Co and Ri will now be described.
100681 In examples described herein, Co is defined as the maximum amount of charge a cell can discharge at a reference current (e.g., 1 A) and reference temperature (e.g., Tni= 25 C). In some embodiments, a raw charge capacity value Co,raw can be computed at the end of a discharge event if the discharge event satisfies certain criteria related to reliability and stability of the Co estimate. For instance, CO,raw for a discharge event can be defined as:
Qdischarge (25) CO,raw = C
where Qaischarge is the total charge discharged by the cell during the discharge event and ASOC is the change in the cell's state of charge during the discharge event.
The raw value of Eq. (25) can be filtered (e.g., using a moving average or other filter function) to provide an estimate of Co.
100691 FIG, 6 is a flow diagram of a process 600 for estimating Co of a cell based on discharge events according to some embodiments. Process 600 can be implemented, e.g., in battery monitoring system 300 or other battery monitoring systems described above. Process 600 can perform Co estimation while the battery is in an Idle state. Process 600 is an example of a passive monitoring process, as it involves no battery activity other than normal operations (i.e., powering a load and/or charging).
[00701 Process 600 can begin while the battery is in an idle state. At block 602, process 600 can determine an initial SOC (SOCaat) for the cell. In some embodiments, the initial SOC can be computed as:
SOCinit = getSOC (Vh,Th) , (26) where Vh is the measured cell potential at the initialization time, Th is the measured temperature at the initialization time, and getS0C() is the same function described above with reference to FIG. 4.
[0071] In some embodiments, SOCinit is only established if the cell potential Vh and temperature 71 are within certain ranges. The ranges can be selected based on the range of potentials and temperatures for which the getS'OC() function is a reliable model of cell behavior. If Vh or Th is outside the appropriate range, then SOCinit is not established.
[0072] In addition to establishing SOCmit, processing at block 602 can also include initializing other parameters used for Co monitoring. For instance, a running total of charge discharged by the cell (goschargo as defined above) can be initialized to zero, and a runtime parameter (t.,co) associated with Co monitoring can also be reset to zero.
[0073] At block 604, the battery enters a Discharging state, and process 600 can monitor the discharge event. (Where process 400 is also implemented, this monitoring can occur as part of the determination of state parameters at block 404.) For instance, the total charge discharged Qdischarge,k can be updated at each time step (e.g., once per second) according to Eq. (3) above, and runtime parameter trun,C0 can be incremented at each time step. At block 606, the discharge event ends and the battery reenters the Idle state (at which point updating of Qdtycharge,k and runtime parameter trun,co can cease).
[0074] At block 608, process 600 can establish a final SOC (SOCfinat) for the cell. In some embodiments, the final SOC can be computed as:
SOCfinat = getS0C(VI,T1) , (27) where VI is the measured cell potential at the end of the discharge event and Ti is the measured temperature at the end of the discharge event. The results of Eqs.
(26) and (27) will generally be different from each other because the after-discharge measurements of VI
and/or Ti generally differ from the pre-discharge measurements of Vh and Th.
[0075] At block 610, process 600 can determine whether all measurements are within ranges such that SOCfina can be considered reliable. For example, in some embodiments, SOCfinat is only established if the cell potential VI and temperature hare within certain ranges. The ranges can be selected based on the range of potentials and temperatures for which the getS0C() function is a reliable model of cell behavior. If VI or Ti is outside the appropriate range, then SOCfinal is not established; instead, the calculation can be reset at block 612, and process 600 can return to block 602 to start over.
[0076] Other requirements related to reliability of SOCfincil can also be applied. For instance, in some embodiments if the runtime parameter trumco exceeds an upper limit, the result may become unreliable (e.g., due to Qthscharge,k integrating a current sensor offset error), and process 600 can rest at block 612 and return to block 602 to start over, [0077] As another example, block 610 can require that the change in SOC, defined as ASO C = ISOCinõ ¨ SOCfhwaI , (28) exceeds a minimum threshold for reliability. The threshold can be chosen to require that the discharge event consumed a significant fraction of the cell's charge capacity;
for instance, the threshold can be 0.4 or 0.5 or the like. If not, the calculation can be reset at block 612, and process 600 can return to block 602 to start over.
[0078] At block 614, process 600 can compute an unfiltered Co value (CO3.) according to Eq. (25), where n ,clischarge is the final value of n clischarge,k from the discharge event at block 604, and AS'OC is given by Eq. (25). At block 616, process 600 can compute a filtered Co value using an infinite impulse response filter that approximates a moving average:
CO,filt = YCo,raw + (1 ¨ y)Comrev, , (29) where CO,prev is a stored estimate of Co (e.g., from a previous iteration of process 600) and y is a filter decay constant that can be chosen based on desired sensitivity to updated values. In one example, y = 0.05; however, other values can be chosen. Other techniques for combining the newly computed Co,raw with previous estimates of Co can be used, including a moving average, weighted moving average (with more recent estimates being given greater weight), recursive moving average, or the like. In some embodiments, a statistical analysis of a distribution of recent estimates of Co for the cell can be performed, e.g., to determine how far outside an expected distribution the most recent Co,raw value is, allowing random measurement noise to be smoothed out. In some embodiments, prior to the first iteration of process 600 for a new cell, CO,prev can be initialized using a charge capacity measured during testing of the cell, a nominal value (e.g., based on the design specification of the cell), or another value as desired.
[0079] At block 618, process 600 can determine whether Copt is implausibly high, e.g., by comparing Cott to a threshold. This threshold can be set to correspond to (or exceed) the maximum charge capacity the cell can be expected to have. In some embodiments, the maximum charge capacity can be determined based on the design specification of the cell, with some allowance for better-than-design performance. In other embodiments, the maximum charge capacity for a specific cell can be determined by actively measuring the charge capacity of the cell during pre-installation testing, on the assumption that the charge capacity of a cell does not increase with use. If Corr is above the threshold, then at block 620, CO,Illt is discarded and process 600 can reset, returning to block 602.
In some embodiments, an implausibly high GOA is assumed to be a numerical artifact and is simply ignored. In other embodiments, process 600 can generate a Co error notification. In still other embodiments, process 600 can track whether implausibly high Copt occurs repeatedly and generate a Co error notification where this is the case.
[0080] In some embodiments, the Co estimate Copt can be used to trigger cell capacity fault notifications. For instance, Co is expected to change slowly over time, and unexpectedly rapid changes may indicate a problem. Accordingly, at block 622, process 600 can compute a change in Co, e.g., using ACo = ICO,prev CO,f itt1 P
(30) and, if ACo exceeds a threshold, the result is treated as suspicious. For instance, at block 624, process 600 can generate a "cell capacity fault" notification. In some embodiments, multiple thresholds can be defined, and different fault notifications can be generated based on which threshold(s) were exceeded. For instance, a "cell capacity suspicious" fault notification can be generated if ACo exceeds a first threshold (e.g., 0.4 Ah), and a "cell capacity very suspicious" fault notification can be generated if ACo exceeds a second, higher threshold (e.g., 0.8 Ah). When a cell capacity fault notification is generated at block 624, process 600 can reset, discarding the result of the Co calculation and returning to block 602.
[0081] At block 626, the stored Co,,rev value can be updated, e.g., by replacing the stored value with Cofift computed at block 616. The updated CO,prev value can be reported to control system 106 or other system components. In some embodiments, control system 106 can incorporate the estimated charge capacity into a battery status report (e.g., for review by service technicians).
[0082] Process 600 can be repeated for every discharge event, assuming the battery enters the Idle state between discharge events. In some embodiments, whenever the battery enters the Idle state, the battery management system can determine whether a valid SOChigh is currently stored. Knot, then block 602 can be performed; if so, then block 608 and subsequent blocks can be performed. In some embodiments, process 600 or a similar process can also be used to estimate Co based on measurements during a charge event.
(This may not be desirable, e.g., if the battery system design is such that measurements of current or other relevant parameters are less reliable during charge events than during discharge events.) [0083] It will be appreciated that process 600 is illustrative and that variations and modifications are possible. To the extent that logic permits, operations described as sequential can be executed in parallel, or operations can be executed in a different order.
Other operations not specifically described can be performed, and operations specifically described can be omitted if desired. For instance, in the examples described, the current estimate and a single value representing a previous estimate are used, but in other implementations, previous estimates from multiple iterations of process 600 can be stored, and a statistical analysis of a set of estimates can be performed. (Such statistical analysis may enhance accuracy and reduce fluctuations but would also increase the amount of memory required to store the previous estimates.) The cell state model and other parameter values in a particular implementation can be selected for optimal results based on the type and properties of battery cell and the particular sensitivity and specificity desired. The Co estimation process can be performed for any number of cells in parallel or sequentially. In some embodiments, if the estimated Co (after filtering) drops below a lower limit, a low Co fault notification can be generated; this may be an indication that the cell is due for replacement.
[0084] In some embodiments, internal resistance RI of a cell can be estimated in addition to or instead of Co. Internal resistance Ri can be defined as the resistance (ohmic) component of the cell's impedance at a standard SOC, current, and temperature and at no cell polarization.
The ohmic component of impedance can be understood as the instantaneous change in potential with respect to current; however, instantaneous measurements of change may not be practical for an operating cell. In addition, internal resistance generally depends on SOC, temperature, and discharge current, so simply measuring AV/A/over a short period may not yield a reliable estimate. Accordingly, some embodiments introduce compensation factors to improve the Ri estimate.
[0085] FIG. 7 is a flow diagram of a process 700 for estimating Ri of a cell based on a discharge event according to some embodiments. Process 700 can be implemented, e.g., in battery monitoring system 300 or other battery monitoring systems described above. Process 700 can perform an iterative (running) RI computation while the battery is actively operating (e.g., in the Discharging or Charging state) and can update the Ri estimate using the running computation when the battery enters Idle state. Process 700 is another example of a passive monitoring process that involves no battery activity other than normal operations.
[0086] Process 700 can begin when the battery transitions from an Idle state to an Active state (e.g., Charging or Discharging state) at block 702. In response to the transition, at block 704, process 700 can initialize a running estimate (RI,ru) of the internal resistance. For example, the running estimate can be initialized to the R, value determined from a previous execution of process 700. In some embodiments, during a first iteration of process 700 for a new cell, can be initialized based on an internal resistance measured during testing of the cell, a nominal value (e.g., based on the design specification of the cell), or another value as desired.
[0087] At block 706, for as long as the battery remains in the Active state, Krun is iteratively updated. (Where process 400 is also implemented, this updating can occur as part of the determination of state parameters at block 404.) FIG. 8 shows a flow diagram of a process 800 for iteratively updating R4run according to some embodiments.
Process 800 can be used, e.g., to implement block 704 of process 700, and process 800 can be performed at regular time intervals (time index k) while the battery is in Active state.
[0088] At block 802, process 800 can measure the current (1k), potential (Vk), and temperature (Tk) of the cell. At block 804, process 800 can check whether reliability conditions on current, potential and temperature are satisfied. For example, the following reliability conditions can be applied:
> Almin (31) > AVinin (32) Tõ,õx mean(Tk,Tk_1) Tmin .
(33) Eqs. (31) and (32) require that the changes in potential and current from one time step to the next be large enough to measure. Eq. (33) requires that the temperature be in a range where the models of resistive behavior used to update &run are considered reliable.
The limiting parameters Alma?, AVnun, &az, and Lnin can be chosen as desired for a particular system. In one example using an implementation of battery bank 200 of FIG. 2, LS/min =2 A, AV-min = 0.010 V, nu= = 50 C, and Tmin = 20 C. Other conditions can also be applied, e.g., upper limits on the change in current and/or potential, and limits on the change in temperature.
[0089] At block 806, if at least one of the reliability conditions of block 804 is not satisfied, process 800 can wait for the next time step at block 808 and try again. If, at block 806, all reliability conditions are satisfied, then at block 810, process 800 can compute a "raw"
estimate Ri,raw for time step k. In some embodiments, the following computation can be used:
Vk Vk-1 (34) Rixaw = r IRComp(SOCk, k,Tk) , k k -1 where SOCk can be determined using the function getS0C(Vk, Tk) function describe above with reference to Eq. (26), and IRComp() is a function that returns an internal resistance compensation factor that depends on SOC, current, and temperature. For example, IRComp() can be defined as:
I RComp(SOC, I, T) = calcRI(SOCref, lõf,Tref) ¨ calcRI(SOC, I, T) .
(35) The function calcRI() can be defined as:
calcIR(SOC, I ,T) = A(SOC, I) * exp (¨B (SOC, I) * (T + 20)) , (36) where A() and B() are functions that can be defined empirically by testing a number of cells of a given design specification under controlled conditions. In some implementations, the empirical analysis can be used to populate a lookup table with values of A() and B() corresponding to various combinations of SOC and I. In Eq. (35), SOCref, /ref, and Tref are constant reference values for SOC, current, and temperature, which can be preselected in connection with defining the functions A() and B() in Eq. (36). For example, the following reference values can be chosen: SOCref= 1, /ref= 22 A, Tpwf= 25 C.
[0090] At block 812, process 800 can determine whether Ri,raw computed at block 810 is within a plausible range. In one example, the plausible range is defined as being between 0.005 and 0.03 SI; other ranges can be used, depending on the design of the cell. If R,raw is not in the plausible range, then at block 814, process 800 can discard or ignore the computed Rixaw value and wait for the next time step to try again. In other embodiments, process 800 can generate an R, error notification. In still other embodiments, process 800 can track whether implausible Ri,renv occurs repeatedly and generate an Ri error notification where this is the case.
[0091] If Ri,raw is in the plausible range, then at block 816, process 800 can update &min using an infinite impulse response filter that approximates a moving average:
krun Ykraw (1 ¨ YYkrun (37) where y is a filter decay constant that can be chosen based on desired sensitivity to updated values. In one example, y = 0.01; however, other values can also be chosen. It should be understood that in embodiments that implement both processes 600 and 800, the decay constant for Ri estimation in Eq. (37) can but need not have the same value as the decay constant for Co estimation in Eq. (29). Other techniques for combining the newly computed Ri,raw with previous estimates of R1 can be used, including a moving average, weighted moving average (with more recent estimates being given greater weight), recursive moving average, or the like. In some embodiments, a statistical analysis of a distribution of recent estimates of Ra for the cell can be performed, e.g., to determine how far outside an expected distribution the most recent &raw value is, allowing random measurement noise to be smoothed out.
[0092] In some embodiments, process 800 (corresponding to block 704 of process 700) can be performed iteratively for as long as the battery remains in Active state.
Referring again to FIG. 7, at block 708, the battery transitions to Idle state. After the battery enters Idle state, the final value of Row, (from process 800) can be used as the new RI estimate.
In some embodiments, the Ri estimate can be used to trigger fault notifications. For instance, R, is expected to change slowly over time, and unexpectedly rapid changes may indicate a problem. Accordingly, at block 710, process 700 can compute a change in Ri, e.g., using:
1R1 = Ifkrun RI
(38) where Ri is the RI value from block 702. If A& exceeds a threshold, the result is treated as suspicious. For instance, at block 714, process 700 can generate a "cell resistance fault"
notification. In some embodiments, multiple thresholds can be defined, and different fault notifications can be distinguished based on which threshold(s) were exceeded.
For instance, a "cell resistance suspicious" fault notification can be generated if AR' exceeds a first threshold (e.g., 0.002 C2), and a "cell resistance very suspicious" fault notification can be generated if ARi exceeds a second, higher threshold (e.g., 0.01 n). When a cell resistance fault notification is generated at block 714, process 700 can discard the resulting Rixun value and return to block 702 to await the next transition to Active state.
[0093] At block 716, the stored Ri value can be updated, e.g., by replacing the stored Ri value with Ri,run. The updated A value can be reported to control system 106 or other system components. In some embodiments, control system 106 can incorporate the estimated internal resistance into a battery status report (e.g., for review by service technicians).
[0094] Process 700 can be repeated, with a new Ri mm being computed (e.g., using process 800) every time the battery enters Active state, and Ri being updated (if conditions are met) when the battery is in Idle state. In some embodiments, process 700 or a similar process can be used to estimate Ri based on either a charge event or a discharge event, or if desired, process 700 may be selectively invoked only in connection with discharge events (or only in connection with charging events).
[0095] It will be appreciated that processes 700 and 800 are illustrative and that variations and modifications are possible. To the extent that logic permits, operations described as sequential can be executed in parallel, or operations can be executed in a different order.
Other operations not specifically described can be performed, and operations specifically described can be omitted if desired. For instance, in the examples described, the current estimate and a single value representing a previous estimate are used, but in other implementations, previous estimates from multiple iterations of process 800 can be stored, and a statistical analysis of a set of estimates can be performed. (Such statistical analysis may enhance accuracy and reduce fluctuations but would also increase the amount of memory required to store the previous estimates.) The cell state model and other parameter values in a particular implementation can be selected for optimal results based on the type and properties of battery cell and the particular sensitivity and specificity desired. The Ri estimation process can be performed for any number of cells in parallel or sequentially. In some embodiments, if the estimated A rises above an upper limit, a high Ri fault notification can be generated; this may be an indication that the cell is due for replacement.
Additional Embodiments [0096] While the invention has been described with reference to specific embodiments, those skilled in the art with access to this disclosure will appreciate that variations and modifications are possible. Battery monitoring systems and processes of the kind described herein can be used to monitor any number of batteries or any number of battery cells, and the systems and processes can be adapted to cells implemented using a variety of battery technologies. Notifications generated during battery monitoring are not limited to the examples given above, and use of notifications is not limited to the use-cases described above. Any combination of monitoring processes can be implemented in a particular system, including any one or more of the processes described above. Functions described as being based on a cell state model (e.g., equivalent cell circuit model) can be implemented by providing a lookup table keyed to the inputs of the function, with appropriate granularity based on the resolution of the measurements of cell state parameters (e.g., the resolution of the potential, current, and temperature sensors). In some embodiments, determination of monitoring parameters can be conditional on the inputs to the function being within the range covered by the lookup table.
[0097] Computational operations of the kind described herein can be implemented in computer systems that may be of generally conventional design, such as a desktop computer, laptop computer, tablet computer, mobile device (e.g., smart phone), or the like. Such systems may include one or more processors to execute program code (e.g., general-purpose microprocessors usable as a central processing unit (CPU) and/or special-purpose processors such as graphics processors (GPUs) that may provide enhanced parallel-processing capability); memory and other storage devices to store program code and data;
user input devices (e.g., keyboards, pointing devices such as a mouse or touchpad, microphones); user output devices (e.g., display devices, speakers, printers); combined input/output devices (e.g., touchscreen displays); signal input/output ports; network communication interfaces (e.g., wired network interfaces such as Ethernet interfaces and/or wireless network communication interfaces such as Wi-Fi); and so on. Computer programs incorporating various features of the claimed invention may be encoded and stored on various computer readable storage media; suitable media include magnetic disk or tape, optical storage media such as compact disk (CD) or DVD (digital versatile disk), flash memory, and other non-transitory media. (It should be understood that "storage" of data is distinct from propagation of data using transitory media such as carrier waves.) Computer readable media encoded with the program code may be packaged with a compatible computer system or other electronic device, or the program code may be provided separately from electronic devices (e.g., via Internet download or as a separately packaged computer-readable storage medium).
100981 It should be understood that all numerical values used herein are for purposes of illustration and may be varied. In some instances ranges are specified to provide a sense of scale, but numerical values outside a disclosed range are not precluded.
[0099] It should also be understood that all diagrams herein are intended as schematic.
Unless specifically indicated otherwise, the drawings are not intended to imply any particular physical arrangement of the elements shown therein, or that all elements shown are necessary. Those skilled in the art with access to this disclosure will understand that elements shown in drawings or otherwise described in this disclosure can be modified or omitted and that other elements not shown or described can be added.
[0100] The above description is illustrative and is not restrictive. Many variations of the invention will become apparent to those skilled in the art upon review of the disclosure. The .. scope of patent protection should, therefore, be determined not with reference to the above description, but instead should be determined with reference to the following claims along with their full scope or equivalents.
Claims (20)
CLAIMED ARE DEFINED AS FOLLOWS:
while the battery cell is in an idle state, determining an initial state of charge of the battery cell; thereafter monitoring a total amount of charge transferred from or to the battery cell while the battery cell is an active state;
after the battery cell returns to the idle state, determining a final state of charge of the battery cell;
computing an unfiltered charge capacity value using the initial state of charge, the final state of charge, and the total amount of charge transferred; and updating a charge capacity estimate using the unfiltered charge capacity value.
computing a magnitude of change in the charge capacity estimate relative to a previous estimate; and generating a cell capacity fault notification in the event that the magnitude of change in the charge capacity exceeds a threshold value.
measuring an initial cell potential and an initial cell temperature of the battery cell while the battery cell is in the initial idle state; and computing a state of charge for the battery cell based on an equivalent cell circuit model using the initial cell potential and the initial cell temperature.
measuring a final cell potential and a final cell temperature of the battery cell when the battery cell returns to the idle state; and computing a state of charge for the battery cell based on the equivalent cell circuit model using the final cell potential and the final cell temperature.
measuring a current through the battery cell at regular time intervals; and adding a product of the measured current and a time step defined by the regular time intervals to a running total of charge transferred.
applying an infinite impulse response filter to the unfiltered charge capacity value and a previously stored charge capacity estimate.
a battery interface to receive sensor data from a battery sensor of a battery cell;
a control system interface to provide output data to a control system;
a memory; and a processor coupled to the memory, the battery interface, and the control system, the processor configured to:
determine, while the battery cell is in an idle state, an initial state of charge of the battery cell; thereafter monitor a total amount of charge transferred from or to the battery cell while the battery cell is an active state;
determine, after the battery cell returns to the idle state, a final state of charge of the battery cell;
compute an unfiltered charge capacity value using the initial state of charge, the final state of charge, and the total amount of charge transferred;
and update a charge capacity estimate stored in the memory using the unfiltered charge capacity value.
compute a magnitude of change in the charge capacity estimate relative to a previous estimate; and generate a cell capacity fault notification in the event that the magnitude of change in the charge capacity exceeds a threshold value.
measuring an initial cell potential and an initial cell temperature of the battery cell while the battery cell is in the initial idle state; and computing a state of charge for the battery cell based on an equivalent cell circuit model using the initial cell potential and the initial cell temperature.
measuring a final cell potential and a final cell temperature of the battery cell when the battery cell returns to the idle state; and computing a state of charge for the battery cell based on the equivalent cell circuit model using the final cell potential and the final cell temperature.
measuring a current through the battery cell at regular time intervals; and adding a product of the measured current and a time step defined by the regular time intervals to a running total of charge transferred.
applying an infinite impulse response filter to the unfiltered charge capacity value and a previously stored charge capacity estimate.
while the battery cell is in an idle state, determining an initial state of charge of the battery cell; thereafter monitoring a total amount of charge transferred from or to the battery cell while the battery cell is an active state;
after the battery cell returns to the idle state, determining a final state of charge of the battery cell;
computing an unfiltered charge capacity value using the initial state of charge, the final state of charge, and the total amount of charge transferred; and updating a charge capacity estimate using the unfiltered charge capacity value.
computing a magnitude of change in the charge capacity estimate relative to a previous estimate; and generating a cell capacity fault notification in the event that the magnitude of change in the charge capacity exceeds a threshold value.
measuring an initial cell potential and an initial cell temperature of the battery cell while the battery cell is in the initial idle state; and computing a state of charge for the battery cell based on an equivalent cell circuit model using the initial cell potential and the initial cell temperature.
measuring a final cell potential and a final cell temperature of the battery cell when the battery cell returns to the idle state; and computing a state of charge for the battery cell based on the equivalent cell circuit model using the final cell potential and the final cell temperature.
measuring a current through the battery cell at regular time intervals; and adding a product of the measured current and a time step defined by the regular time intervals to a running total of charge transferred.
applying an infinite impulse response filter to the unfiltered charge capacity value and a previously stored charge capacity estimate.
Priority Applications (1)
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| CA3219639A CA3219639A1 (en) | 2020-03-12 | 2021-03-10 | Real-time battery fault detection and state-of-health monitoring |
Applications Claiming Priority (5)
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| US202062988853P | 2020-03-12 | 2020-03-12 | |
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