WO2000075678A1 - Battery capacity measurement - Google Patents
Battery capacity measurement Download PDFInfo
- Publication number
- WO2000075678A1 WO2000075678A1 PCT/NZ2000/000089 NZ0000089W WO0075678A1 WO 2000075678 A1 WO2000075678 A1 WO 2000075678A1 NZ 0000089 W NZ0000089 W NZ 0000089W WO 0075678 A1 WO0075678 A1 WO 0075678A1
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- WIPO (PCT)
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- battery
- voltage
- discharge
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- parameter
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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]
- G01R31/382—Arrangements for monitoring battery or accumulator variables, e.g. SoC
- G01R31/3835—Arrangements for monitoring battery or accumulator variables, e.g. SoC involving only voltage measurements
Definitions
- the invention relates to a method of obtaining information relating to the charge capacity of a battery. It relates in particular, although not exclusively, to a method of obtaining information relating to the charge capacity of a battery which is in a fully charged condition, without the need to fully discharge the battery.
- the existing battery capacity measurement techniques are either not acceptable to the telecommunications community because they leave a system vulnerable to failure, demand high cost, impose long delays between testing, require manual measurement procedure, or are not allowed due to telecommunications standards (as is the case with rectification noise levels).
- a full discharge test into a stable load is recommended by industry and professional institutions as the only reliable approach for battery capacity measurement and is often referred to as the "capacity test” .
- This approach suffers from substantial disadvantages including the requirement of bulky external loads, the need for backup power supplies, and the labour required to set up and supervise the procedure.
- Lately impedance/conductance techniques have become popular for obtaining estimates of battery capacity. These techniques require the use of specialised equipment. In addition there is some uncertainty surrounding their effectiveness with most of the researchers dealing with these techniques being reluctant to promote them as a replacement to the "capacity test" .
- Accumulation type techniques depend on an estimation of charging efficiency and require correction factors for different discharge temperatures and rates. In addition they are not tolerant to disruptions to their short term data history.
- Curve fitting and parametric models are two other common approaches which also suffer from the requirement of correction factors for different discharge temperature and rates. Curve fitting models try to match the discharge voltage versus time curve to either an exponential parabolic or hyperbolic curve. Some models employ more complex hybrid approaches. The major disadvantage with these models is that for each combination of discharge conditions and battery type a parameter set is required. These parameter sets are obtained through an exhaustive series of discharge tests. Parametric models are based on internal battery parameters such as internal resistance. Models such as this estimate SOC (state of charge) or reserve time by redrawing the manufacturers discharge voltage time curves based on the change in internal resistance. Battery resistance, however, is not always supplied by the manufacturer and therefore must be measured.
- the present invention seeks to provide a method by which at least some of the aforedescribed disadvantages are mitigated or overcome. It seeks to provide a method which at the least provides information concerning the capacity of one battery relative to that of another battery, and/or the capacity as influenced by the operating conditions and optionally additionally or alternatively information concerning the absolute or intrinsic charge capacity of a battery. Summary of the Invention
- the invention provides a method of obtaining information relating to the charge capacity of one or more cells including: measuring a variable cell parameter, or change in a variable cell parameter, for at least a part of an initial period of discharge during which the cell voltage initially decreases to a trough voltage and then increases to a plateau voltage; and relating the variable cell parameter, or change in the variable cell parameter, to reference information to obtain the absolute or relative charge capacity of the cell or cells.
- the invention provides a method of estimating the capacity of a battery including: acquiring reference information relating a variable battery parameter, or change in a variable battery parameter, to one or more operating conditions and/or battery condition; measuring the variable battery parameter, or change in the variable battery parameter, during at least part of an initial discharge period of the battery, during which the voltage initially decreases to a trough voltage and then increases to a plateau voltage; and relating the variable battery parameter, or change in variable battery parameter, to reference information to obtain an absolute or relative capacity of the battery.
- the variable cell parameter may be measure with respect to a single electrode.
- the invention envisages that preferably, but not exclusively, measurements are made of cell or electrode voltage, or change of voltage with time, for at least a part of the period of time during which the battery voltage initially decreases to a trough voltage and then increases to a plateau voltage.
- the initial period during which the battery output voltage initially decreases to a trough voltage and then increases to a plateau voltage is the Coup De Fouet period.
- the reference information is the relationship between one or more battery operating conditions and/or battery condition and the trough voltage or plateau voltage of the Coup De Fouet period.
- the operating conditions may be one or more of time on charge and/or depth of previous charge and/or float voltage and/or ambient temperature and/or discharge rate.
- the reference information is acquired when the battery is in the early stages of its operational life.
- the battery is in a substantially fully charged condition.
- Measurement of the variable battery parameter may occur when the battery is subjected an initial period of discharge (a discharge test) or when the battery begins to discharge when required to supply a load. Thus, when a battery begins to discharge into a load the discharge time remaining may be calculated. Alternatively, to determine remaining operational life of the battery it may be subjected to a discharge test.
- the method may include use of discrimination means which compares a change of a measured or monitored variable parameter with a change which is compatible with that which occurs in the Coup De Fouet period of initial discharge and responds to whether or not that compatibility is present.
- discrimination means which compares a change of a measured or monitored variable parameter with a change which is compatible with that which occurs in the Coup De Fouet period of initial discharge and responds to whether or not that compatibility is present.
- the method of the invention comprises a search for the occurrence of the trough or plateau voltage, and measurement of that trough and/or plateau voltage from which capacity is determined using a parameterised relationship.
- the invention is intended particularly for measurement of the capacity, or relative capacity, of a battery of a kind in which electrical discharge results in a chemical reaction that produces reaction discharge products.
- batteries typically exhibit the Coup De Fouet characteristic during initial discharge from a fully charged condition, with the voltage initially reducing to a trough voltage and then increasing to a plateau voltage from which it then decreases progressively as the battery is discharged.
- this invention may be utilised in respect of electrochemical batteries where at least one of the electroactive components is in the liquid phase and therefore under diffusion control, such as a lead/acid battery where the sulphuric acid takes part in the discharge and recharge reactions.
- the invention may be applied to lead/acid type batteries and other batteries which are re-chargeable.
- use of the invention to measure the charge of batteries of a non- rechargeable type is not excluded.
- the period of discharge necessary to establish information related to battery charge capacity by the method of the present invention is substantially less than the time taken for full discharge, and the loss of charge for the purpose of charge determination also is substantially less.
- a short discharge test of not more than 1 0% of nominal capacity in discharge depth is found to be sufficient to reveal information related to the absolute or relative charge capacity of the battery.
- a discharge of not more than 5 % and more preferably not more than 1 % of nominal capacity may be employed.
- the invention envisages that preferably, but not exclusively, the function of one or more of the above steps is performed by a computer.
- the invention further provides for an estimation model for predicting the absolute or relative capacity of a battery, including: input for a variable battery parameter, and one or more battery operating conditions and/or battery condition; reference information relating variable battery parameter to one or more battery operating conditions and/or battery condition; compensation means determining correction factor for variable battery parameter depending on value any one of battery operating conditions and/or battery condition; and calculation means relating corrected variable battery parameter to reference information to obtain the absolute or relative charge capacity of the battery.
- the method may include use of training or learning means adapted to determine reference information relating a variable battery parameter to one or more battery operating conditions and/or battery condition; or to determine rules relating variable battery parameter, or change in variable battery parameter, to one or more battery operating conditions and/or battery condition.
- training or learning means may be any one of an Adaptive Neural Fuzzy Interface System or an Adaptive Network, or other Neuro-Fuzzy or Soft Computing system.
- the estimation model may be in the form of computer readable code.
- an apparatus adapted to provide information relating to the charge capacity of a battery, including: measurement means adapted to measure a variable battery parameter, or change in variable battery parameter; and processing means adapted to relate the variable battery parameter, or change in variable battery parameter, to reference information to obtain the absolute or relative charge capacity of the battery.
- the apparatus may measure voltage, or change of voltage, for at least part of an initial period of discharge of a battery during which the battery voltage initially decreases to a trough voltage and then increases to a plateau voltage; and may also measure one or more battery operating conditions.
- the apparatus includes a microprocessor adapted to manipulate a variable battery parameter, or change in variable battery parameter, and one or more battery operating conditions and/or battery condition and output an estimation of the absolute or relative charge capacity of the battery.
- the microprocessor may be adapted to output the discharge time remaining expressed in hours and fractions of an hour, and/or be adapted to output the remaining operational life of the battery.
- the output means may be graphical, numerical or otherwise.
- the apparatus may further include a discharge means, the discharge means adapted to at least partially discharge a battery and measure the variable battery parameter, or change in variable battery parameter, for at least part of the partial discharge.
- the apparatus may also include training or learning means adapted to determine rules relating a variable battery parameter, or change in a variable battery parameter, to one or more battery operating conditions and/or battery condition.
- FIGURES 1 a - 1d illustrates the Coup De Fouet region during cell discharge
- FIGURES 2a - 2d illustrates the shape of the Coup De Fouet for previous discharges to various depths
- FIGURES 3a - 3d illustrates the dependence of the Coup De Fouet on the time on charge
- FIGURES 4a - 4b illustrates the influence of float voltage on Coup De Fouet
- FIGURES 5a - 5b illustrates the shape of the Coup De Fouet for various discharge rates
- FIGURES 6a - 6b illustrates the shape of the Coup De Fouet for various ambient temperatures
- FIGURES 7a - 7b illustrates the relation between Coup De Fouet and capacity for different discharge rates
- FIGURES 8a - 8b illustrates the relation between Coup De Fouet and capacity for different ambient temperatures
- FIGURES 9a - 9d illustrates the influence of accelerated thermal ageing on Coup De Fouet
- FIGURES 10a-10d illustrates the influence of accelerated thermally and water replenishment on Coup De Fouet
- FIGURE 1 1 illustrates a fuzzy logic correction model employed for capacity estimation
- FIGURE 12 illustrates a Coup De Fouet capacity estimation model
- FIGURES 13a-13b illustrates the results of the capacity estimation model
- TABLE 1 Shows data for the original and post ageing capacity of cells
- the Coup De Fouet is an electrochemical phenomenon.
- the invention is intended particularly for measurement of the capacity, or relative capacity, of a battery of a kind in which electrical discharge results in a chemical reaction that produces reaction discharge products.
- Such batteries typically exhibit the Coup De Fouet characteristic during initial discharge from a fully charged condition, with the voltage initially reducing to a trough voltage and then increasing to a plateau voltage from which it then decreases progressively as the battery is discharged.
- this invention may be utilised in respect of electrochemical batteries where at least one of the electroactive components is in the liquid phase and therefore under diffusion control, such as a lead/acid battery where the sulphuric acid takes part in the discharge and recharge reactions.
- the invention may be applied to lead/acid type batteries and other batteries which are re-chargeable.
- the voltage drops quickly to a trough voltage and then increases to a peak, plateau voltage within about 4 to 5 minutes from initial discharge. The voltage then gradually reduces as the cell discharges.
- the invention identifies that the level of the trough and plateau voltages during the Coup De Fouet period are influenced by the operating conditions and condition of the battery. Typical operating conditions which effect the Coup De Fouet are depth of previous discharge, time on float charge, float voltage, ambient temperature and discharge rate. The effect that each of these conditions has on Coup De Fouet is discussed in turn.
- Figures 2a to 2d illustrate consecutive discharges of an Oldham 2HI275 cell to various depths.
- the discharge rate was 100A and the ambient temperature was 20°C.
- After each discharge 1 10% of the charge released during the discharge was supplied to the cell and then it was charged for a further 24 hours. Under these operating conditions the cell is rated to release 1 77Ah of charge when discharged to a depth of 1 .85V.
- Figure 2a illustrates discharges to a depth of 1 % ( ⁇ 1 .8Ah) .
- the first discharge is normal with the voltage decreasing to the trough before recovering.
- Figures 3a to 3d illustrate the dependence of the Coup De Fouet on the time on charge.
- Figure 3a illustrates the Coup De Fouet region of consecutive discharges to a depth of 1 2.5% of an Oldham 2HI275 cell at a rate of 100A and ambient temperature of 20°C.
- Figure 3b illustrates the trough region in greater detail. It is apparent that the longer the cell is charged, the deeper the trough voltage is. This is clear from Figures 3c and 3d where the trough and plateau voltages are plotted against charge time respectively.
- FIG 4a illustrates consecutive discharges of an Oldham cell to a depth of 1 2.5 % at a rate of 100A and ambient temperature of 20°C. Between each discharge the cell was recharge for a fixed period of 30 hours utilising float voltages of 2.22, 2.27 and 2.32V. The nominal float voltage for the operating conditions is 2.27V.
- Figure 4b illustrates the relation between the float voltage and the trough and plateau voltages. It is apparent that the lower the float voltage the lower the trough and plateau voltages.
- Tests were conducted to establish the relationship between capacity and Coup De Fouet for different combinations of discharge rate and ambient temperature.
- the battery when configured as a 1 2 volt string and discharged at 100 amps over a period of about 2 hours.
- the discharge profiles of those cells during the initial Coup De Fouet period are summarised below.
- Figure 6a shows seven discharge voltages vs. time profiles for the cells when being discharged at different ambient temperatures. The results for the Coup De Fouet period are shown in more detail by Figure 6b.
- Figure 7a and 7b and Figure 8a and 8b illustrate the key results from these tests.
- Figures 7a and 7b illustrate the relation between capacity due to the use of various discharge rates and the trough and plateau voltage parameters respectively.
- Figures 8a and 8b illustrate the relation between capacity due to the use of various ambient temperatures and the trough and plateau voltage parameters respectively. For both operating conditions and for both parameters (the trough and plateau voltage) the relations are close to linear. This examination of the voltage of the battery during the Coup De Fouet period may be used to conveniently provide information related to the battery capacity.
- Determining the capacity due to operating conditions is helpful if prompt time remaining information is required at the start of a discharge.
- the ultimate aim is to determine the capacity due to the condition of the battery alone and not the operating conditions.
- the effects of battery condition on the Coup De Fouet must be determined. Investigations were undertaken to determine the influence of battery condition on the Coup De Fouet due to two modes of battery degradation. The first mode is accelerated thermal ageing. The 5 second mode is the result of replenishing the water lost from the cells which had undergone the accelerated thermal ageing.
- Accelerated ageing is commonly used to rate a battery's operational life.
- the experiment was conducted by charging four pairs of Oldham 2HI275 cells at the ⁇ o nominal 20°C float voltage of 2.27V, and ambient temperature of 71 °C, for from 2 to 5 periods. Each period consisted of 1 3 days. A further pair of cells were charged under standard conditions (2.27V, 20°C ambient temperature). As a result, after discharging at a rate of 100A to an end voltage of 1 .85V, the cells exhibited capacities of between 1 0% and 1 23% of manufacturers rated capacity ( 1 77Ah) .
- the original and post ageing capacities are given in Table 1 .
- the original capacity is given as a percentage related to the ten hour discharge to an end voltage of 1 .75V.
- the important point to note is the consistency of the cells original capacity and the variation in the cells capacity after ageing .
- the cells were weighed prior to undergoing the accelerated ageing. After the accelerated ageing they were re-weighed with the resulting difference in weight giving an indication in the amount of water lost during the process.
- the pre and post ageing weights along with the weight differences are given in Table 2.
- Figures 9a to 9d illustrate the effect of accelerated thermal ageing on the Coup De Fouet.
- Figure 9a illustrates the entire discharge voltage profiles of each pair of cells and
- Figure 9b illustrates a close up of the Coup De Fouet region of the discharges.
- the cells which have the lowest capacity have a lower Coup De Fouet (trough 30 and plateau voltages) .
- the relation between the capacity due to the degradation in battery condition with the trough and plateau voltages is illustrated in Figures 9c and 9d respectively. It can be seen here that in both cases the relation is close to linear.
- Table 2 it was possible to replenish the water lost through the thermal ageing process. The cells were then re-charged and discharged.
- the knowledge gathered by conducting the above tests represents a baseline for the rules of this model.
- the following paragraphs present the structure of the model and the result of its application.
- the following discussion will consider only the trough voltage.
- the trough is targeted as it occurs close to the start of discharge.
- a discharge to the trough will result in minimal impact on the power system and battery life. It is also easy to detect due to the sudden voltage reversal.
- the discussion may be applied equally to the plateau voltage.
- the knowledge of the relations between operating conditions and the trough voltage are contained within a fuzzy logic model.
- Such models are within the capabilities of the skilled addressee with one particular model, the Sugeno Fuzzy Model, being discussed by T. Takag and M. Sugeno in "Fuzzy Identification Systems and its Application to modelling and control", IEEE Trans, Systa, Man Cybern, Vol. 1 5, pp. ⁇ o 1 1 6-1 32, 1 985; the contents of which is considered included in this specification as if it were individually set forth.
- the Sugeno Fuzzy Model is illustrated in Figure 1 1 .
- the fuzzy model has as inputs the operating conditions of time on charge, float voltage, depth of previous discharge, discharge rate and ambient temperature. Each input utilises three membership functions.
- the output of the model is a correction factor which also utilises three membership functions. This correction factor is applied to the Coup De Fouet parameters associated with the operating conditions to cancel their effect.
- ANFIS Adaptive Neural Fuzzy Inference System
- the overall structure of the estimation model is illustrated in Figure 1 2.
- the model is implemented using Matlab's Simulink.
- the inputs are fed into the fuzzy model which produces a correction factor.
- This correction factor is added to the trough voltage corresponding to the inputs to eliminate the influence of the operating conditions.
- a simple linear relation is used to scale the trough voltage to determine the capacity.
- This summation and scaling activity is the hard computing aspect of the model.
- soft computing techniques could also be used to replace this hard computing aspect.
- the period of discharge necessary to establish information related to battery charge capacity by the method of the present invention is substantially less than the time taken for full discharge, and the loss of charge for the purpose of charge determination also is substantially less.
- a short discharge test of not more than 1 0% of nominal capacity in discharge depth is found to be sufficient to reveal information related to the absolute or relative charge capacity of the battery.
- a discharge of not more than 5% and more preferably not more than 1 % of nominal capacity may be employed.
- the soft-computing component may be in another form such as a pattern recognition based model.
- Soft computing may also
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Application Number | Priority Date | Filing Date | Title |
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AU49597/00A AU4959700A (en) | 1999-06-03 | 2000-06-02 | Battery capacity measurement |
EP00931767A EP1188063A1 (en) | 1999-06-03 | 2000-06-02 | Battery capacity measurement |
US09/979,906 US6924622B1 (en) | 1999-06-03 | 2000-06-02 | Battery capacity measurement |
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GB9912778.9 | 1999-06-03 | ||
GB9912778A GB2350686B (en) | 1999-06-03 | 1999-06-03 | Battery capacity measurement |
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EP (1) | EP1188063A1 (en) |
AU (1) | AU4959700A (en) |
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WO (1) | WO2000075678A1 (en) |
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Also Published As
Publication number | Publication date |
---|---|
GB2350686A (en) | 2000-12-06 |
EP1188063A1 (en) | 2002-03-20 |
GB2350686A8 (en) | 2004-04-28 |
GB9912778D0 (en) | 1999-08-04 |
AU4959700A (en) | 2000-12-28 |
GB2350686B (en) | 2004-01-07 |
US6924622B1 (en) | 2005-08-02 |
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