Method for prediction of the internal resistance of an energy storage battery, and a monitoring device for energy storage batteries

Information

  • Patent Grant
  • 7098665
  • Patent Number
    7,098,665
  • Date Filed
    Monday, November 10, 2003
    21 years ago
  • Date Issued
    Tuesday, August 29, 2006
    18 years ago
Abstract
A method for predicting the internal resistance of an energy storage battery in assumed environmental and battery state conditions includes subdividing the internal resistance into a first resistance component which represents the electrical resistance of the energy storage battery for the region of electron conduction and a second resistance component which represents the electrical resistance of the energy storage battery for the region of ion conduction. The method also includes determining the first and second resistance components to be expected for the assumed environmental and battery state conditions. Each of the first and second resistance components are determined as a function of parameters of the assumed environmental and battery state conditions. Monitoring devices or computer programs may be utilized to carry out the method.
Description
CROSS-REFERENCE TO RELATED PATENT APPLICATIONS

Germany Priority Application DE 102 52 760.1, filed Nov. 13, 2002, including the specification, drawings, claims and abstract, is incorporated herein by reference in its entirety.


BACKGROUND OF THE INVENTION

The present invention relates to a method for prediction of the internal resistance of an energy storage battery in assumed environmental and battery state conditions. The present invention also relates to a monitoring device for energy storage batteries having measurement means for measurement of parameters for the environmental and battery state conditions for the energy storage battery and also having computation means. The present invention also relates to a product in the form of a computer program with program code means for carrying out the method mentioned above.


During operation of energy storage batteries, in particular starter batteries in motor vehicles, there is a need to determine the instantaneous state of the energy storage battery and to predict a future state in assumed environmental and battery state conditions. For example, it is desirable to determine the starting capability of a starter battery for starting an internal combustion engine in assumed temperature conditions. It is known for the instantaneous internal resistance to be determined for this purpose. This may be done, for example, from the drop in voltage on starting as the quotient of the voltage change divided by the current change. The internal resistance may also be obtained by matching the voltage and current information for the energy storage battery to a relatively complex equivalent circuit. An internal resistance determined in this way may then be used as a prognosis for a future starting process.


DE 198 47 648 A1 discloses a method for determination of the state of charge and of the high-current load capacity of batteries, in which the internal resistance of the battery is determined by means of a voltage and current measurement on high load, for example, during the starting process. Furthermore, the state of charge SOC of the energy storage battery is determined in a first state. This is done, for example, by measurement of the no-load voltage. The internal resistance is subdivided into a part which is only temperature-dependent and is virtually independent of the state of charge, and into a component which varies to a major extent with the state of charge for states of charge below 50%. A no-load voltage for a subsequent time is predicted from the internal resistance that has been subdivided in this way for a predetermined temperature and from the most recently determined state of charge, from which no-load voltage it is possible to use the known current required for starting an internal combustion engine to derive a statement about the capability of the energy storage battery for starting.


It would be advantageous to provide an improved method for predicting the internal resistance of an energy storage battery in assumed environmental and battery state conditions, by means of which, for example, the starting capability of a starter battery for a motor vehicle for a subsequent time can be predicted. It would be also advantageous to provide a monitoring device for energy storage batteries having measurement means for measurement of parameters for the environmental and operating state conditions for the energy storage battery, and having computation means which are designed to carry out the method described above. It would be also advantageous to provide a product in the form of an embodied computer program with program code means which are designed to carry out the method described above when the computer program is run using a processor device.


It would be advantageous to provide a system and/or method that includes any one or more of these or other advantageous features.


SUMMARY

An exemplary embodiment relates to a method for predicting the internal resistance of an energy storage battery in assumed environmental and battery state conditions. The method includes subdividing the internal resistance into a first resistance component which represents the electrical resistance of the energy storage battery for the region of electron conduction and a second resistance component which represents the electrical resistance of the energy storage battery for the region of ion conduction. The method also includes determining the first and second resistance components to be expected for the assumed environmental and battery state conditions. Each of the first and second resistance components are determined as a function of parameters of the assumed environmental and battery state conditions.


Another exemplary embodiment relates to a monitoring device for an energy storage battery. The monitoring device includes a measurement device for measuring parameters for the environmental and operating state conditions of the energy storage battery. The monitoring device also includes a computation device configured to carry out a method that includes subdividing the internal resistance of the energy storage battery into a first resistance component which represents the electrical resistance of the energy storage battery for the region of electron conduction and a second resistance component which represents the electrical resistance of the energy storage battery for the region of ion conduction. The method also includes determining the first and second resistance components to be expected for assumed environmental and battery state conditions. Each of the first and second resistance components are determined as a function of parameters of the assumed environmental and battery state conditions.


Another exemplary embodiment relates to a computer program that includes computer program code that when run using a processor device is configured to carry out a method that includes subdividing the internal resistance of an energy storage battery into a first resistance component which represents the electrical resistance of the energy storage battery for the region of electron conduction and a second resistance component which represents the electrical resistance of the energy storage battery for the region of ion conduction. The method also includes determining the first and second resistance components to be expected for assumed environmental and battery state conditions. Each of the first and second resistance components are determined as a function of parameters of the assumed environmental and battery state conditions.





BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be explained in more detail in the following text with reference to the attached drawings, in which:



FIG. 1 shows a block diagram illustrating the subdivision of the internal resistance into a first resistance component and a second resistance component, with associated functions;



FIG. 2 shows a graph illustrating the specific resistance of lead as a function of temperature as a first function for determining the first resistance component;



FIG. 3 shows a graph illustrating the specific conductivity of sulfuric acid as a function of the no-load voltage which results for various acid concentrations in a single cell as a basic family of functions for determination of the second function in order to establish the second resistance component;



FIG. 4 shows a graph illustrating the specific conductivity of sulfuric acid as a function of the temperature for no-load voltages which occur with different acid concentrations, as an inverse second function for determination of the second resistance component.





DETAILED DESCRIPTION OF THE PREFERRED AND EXEMPLARY EMBODIMENTS

According to an exemplary embodiment, a method is provided for predicting the internal resistance of a battery (e.g., an energy storage battery such as a lead-acid battery for use in vehicle starting, lighting, and ignition applications) in assumed environmental and battery state conditions, by means of which, for example, the starting capability of a starter battery for a motor vehicle for a subsequent time can be predicted, at which the temperature and/or the state of charge of the energy storage battery has changed considerably, for example, due to residual current loads.


According to an exemplary embodiment, the method includes subdividing the internal resistance at least into a first resistance component (which represents the electrical resistance of the energy storage battery for the region of electron conduction) and a second resistance component (which represents the electrical resistance of the energy storage battery for the region of ion conduction). The method also includes determining the resistance components to be expected for the assumed environmental and battery state conditions, in each case as a function of parameters of the assumed environmental and battery state conditions.


It has been found that the relationships between the internal resistance and the state of charge and temperature as parameters for the environmental and battery state conditions for metallic output conductors (i.e., for the region of electron conduction) are very different from the internal resistance for electrolytes (i.e., for the region of ion conduction). In this case, relatively simple functional relationships with the parameters for the environmental and battery state conditions in each case exist for the first resistance component for the metallic output conductors and for the second resistance component for the electrolytes. Separating the internal resistance into the first resistance component and second resistance component resolves the complex relationship between the internal resistance and the environmental and battery state conditions, breaking it down into relatively simple functional relationships.


The resistance components are advantageously calculated from a factor multiplied by a battery-independent function. The first factor for the first resistance component and the second factor for the second resistance component are in this case defined or determined as a function of the type of energy storage battery. The first resistance component is then determined from the first factor and from a battery-independent first function of parameters for the environmental conditions for the energy storage battery, and the second resistance component is determined from the second factor and from a battery-independent second function for environmental and battery state conditions for the energy storage battery. As a result, only the first and second factors for the energy storage battery need be defined or learned. In contrast, the first and second functions are independent of the battery type and can thus be determined and defined on a general basis. It is thus possible to predict the internal resistance for unknown energy storage batteries once the first and second factors have been learned as a function of the battery type.


The first and second factors are preferably determined by determination of parameters and internal resistances for at least two environmental and/or battery state conditions which differ from one another. After estimation of one of the factors and determination of the parameters for two environmental and/or battery state conditions which differ from one another, in particular for two different temperatures, the system may calculate the first factor and the second factor with a sufficient degree of accuracy.


A variable which is proportional to the battery temperature is preferably used as a parameter for determination of the first resistance component. A variable which is proportional to the battery temperature and a variable which is proportional to the state of charge of the energy storage battery are preferably used as parameters for determination of the second resistance component The battery or environmental temperature may be measured, for example, as a temperature parameter, that is to say as a variable which is proportional to the battery temperature. The variable which is proportional to the state of charge of the energy storage battery is preferably the no-load voltage of the energy storage battery. The internal resistance of the energy storage battery is also determined as a parameter, in a known manner.


The first and second factors are preferably determined iteratively by means of the following steps:


a) estimation of the first factor;


b) determination of the second factor as a function of the estimated first factor and of parameters which have been determined for first environmental and battery state conditions;


c) determination of a corrected first factor for changed second environmental and/or battery state conditions as a function of the previously determined second factor and of the parameters determined for the second environmental and battery state conditions; and


d) determination of the second factor as a function of the corrected first factor and of the parameters determined for the first or second environmental and battery state conditions.


In this case, steps c) and d) may be repeated as often as desired in order to improve the accuracy of the first and second factors.


The first and second factors determined in this way are used to determine the first resistance component using the formula

RMet=RfactMet(T0r(T)


where RFactMet (T0) is the first factor for a reference temperature (T0) and r(T) is a first function which is dependent on the battery temperature T. The first function r(T) may, for example, be defined as an equation

r(T)=l+k·(T−T0)+l(T−T0)2

with the constants k and l. According to an exemplary embodiment, the constant k is equal to 0.00334 and the constant l may be equal to zero for a lead-acid rechargeable battery with six cells.


The second resistance component is determined, for example, using the formula

RElyt=l/(Lfact·f(T,SOC))

where Lfact is the second factor and f(T, SOC) is a second function which is dependent on the battery temperature T and on the state of charge parameter SOC for the energy storage battery.


The second function f(T, SOC) may, for example, be defined as an equation

f(T,SOC)=(a+b·SOC+c·SOC2)·(l+d(T−T0)+e(T−T0)2)

with the constants a, b, c, d and e and the reference temperature T0. For a lead-acid battery with six cells, the constant a is preferably approximately 0.451, the constant b is preferably approximately 1.032, the constant c is preferably approximately −0.697, the constant d is preferably approximately 0.0137 and the constant e is preferably approximately 0. The reference temperature is preferably defined to be 25° C.


In order to make it possible to take account, for example, of uncertainties resulting from measurement inaccuracies and scatter associated with these inaccuracies, the first factor is preferably corrected by determination of an instantaneous first factor for instantaneous environmental and battery state conditions and calculation of the corrected first factor from the instantaneous first factor and from at least one weighted previously determined first factor. The second factor can also be corrected in a corresponding manner by determination of an instantaneous second factor for instantaneous environmental and battery state conditions and calculation of the corrected second factor from the instantaneous second factor and from at least one weighted previously determined second factor. The instantaneously determined first and second factors are thus not transferred directly. In fact, a weighted influence from previously determined factors is retained.


According to an exemplary embodiment, the first factor for the reference temperature T0 is preferably calculated using the formula








Rfact
Met



(

T
0

)


=




R
1

·

f


(


T
1

,

SOC
1


)



-


R
2

·

f


(


T
2

,

SOC
2


)







r


(

T
1

)


·

f


(


T
1

,

SOC
1


)



-


r


(

T
2

)


·

f


(


T
2

,

SOC
2


)










where R1 is the internal resistance, T1 is the battery or environmental temperature, and SOC1 is the state of charge parameter at the time of a first measurement for the first environmental and battery state conditions, and R2 is the internal resistance, T2 is the battery or environmental temperature, and SOC2 is the state of charge parameter at the time of a second measurement for the second environmental and battery state conditions.


The second factor is preferably calculated using the formula

Lfact=l/([Ri−RfactMet(T0r(Ti)]·f(Ti,SOCi),

where Ri is the internal resistance, Ti is the battery or environmental temperature, and SOCi is the state of charge parameter at the time i of a measurement.


It is particularly advantageous not only to subdivide the internal resistance into the first and second resistance components but also into a third resistance component for the region of the positive active mass of the energy storage battery and/or into a fourth resistance component for the region of the negative active mass of the energy storage battery, and to determine the third and/or fourth resistance components using the method as described above, in each case using an associated factor and an associated function, as a function of parameters for the environmental and battery state conditions.


The predicted internal resistance is preferably used to make a prediction about the state of the energy storage battery, for example the wear, the performance or the functionality of the energy storage battery.



FIG. 1 is a diagram relating to the subdivision of the internal resistance Ri of an energy storage battery into a first resistance component RMet and a second resistance component RElyt. The first resistance component RMet represents the electrical resistance of the energy storage battery for the region of electron conduction. This first resistance component is composed of the metallic resistances of an energy storage battery, in particular of the terminal bolts, terminal links, terminal connectors and lead grating in a lead-acid rechargeable battery. The second resistance component represents the electrical resistance of the energy storage battery for the region of ion conduction, that is to say the resistance contribution to the electrolyte paths, in particular the space between the electrodes and the electrode pores that are filled with electrolyte.


In the case of lead-acid rechargeable batteries, further contributions to the electrical resistance of the first resistance component can be ignored, in particular the resistance contributions from the positive and negative active materials. These resistance components may, however, also be taken into account as further additive resistance components, corresponding to the first and second resistance components, when determining the internal resistance.


The method according to an exemplary embodiment will be explained in the following text using the example of a lead-acid rechargeable battery. However, the method is not restricted to lead-acid rechargeable batteries, but can also be applied in a corresponding manner to other types of rechargeable batteries.


The internal resistance Ri is calculated as:

Ri=RMet+RElyt.


The first resistance component RMet is preferably calculated from a factor RfactMet and from a battery-independent first function r(T) of parameters of the environmental conditions for the energy storage battery using the formula:

RMet=RfactMet(T0r(T)

where T0 is a reference temperature and T is the environmental or battery temperature.


The second resistance component RElyt is determined from a second factor Lfact and from a battery-independent second function f(T,SOC) of the environmental and battery state conditions for the energy storage battery using the formula

RElyt=l/(Lfact·f(T,SOC))

with SOC being a state of charge parameter which describes the state of charge of the energy storage battery. The state of charge SOC is the difference between the rated capacitance of the energy storage battery and the amount of charge drawn from it with respect to the rated capacity. In the case of a lead-acid rechargeable battery, there is a unique and largely linear relationship between the no-load voltage U00 and the state of charge SOC, since the no-load voltage U00 depends on the electrolyte concentration, which in turn depends on the state of charge. The no-load voltage U00 can thus be chosen as an equivalent parameter, instead of the state of charge itself, as the state of charge parameter. This has the advantage that the no-load voltage U00 can be measured relatively easily.


As can be seen from the formulae mentioned above, the first resistance component RMet does not depend on the state of charge parameter SOC but only on the temperature T. The second resistance component RElyt, on the other hand, depends on the acid concentration and thus also uniquely on the no-load voltage U00 of the energy storage battery as a measure of the electrolyte concentration and of the state of charge of the energy storage battery. The second resistance component RElyt also depends to a relatively major extent on the temperature T.


By way of example, FIG. 2 shows a diagram or graph illustrating the specific resistance r of lead as a function of the temperature T. As can be seen, there is a linear relationship between the specific resistance of lead and the temperature T. Since the first resistance component RMet is determined essentially by the resistances of the metallic lead output conductors from the lead-acid battery, the first function r(T) for calculation of the first resistance component RMet can be derived directly from the temperature-dependent specific resistance r. This function of the specific resistance r, as a function of the temperature, can also be used directly as the first function. The first resistance component RMet is then calculated from the quotient of this first function r(T) and a first battery-dependent factor which, in particular, reflects the cross-sectional area of the lead.



FIG. 3 shows the specific conductivity g of sulfuric acid as a function of the no-load voltage U00 that is produced for various acid concentrations in an individual cell at temperatures T in the range from 20° C. to 40° C. The second resistance component RElyt is governed essentially by this sulfuric acid conductivity, which is dependent on the temperature and on the acid concentration.



FIG. 4 is a diagram or graph illustrating the specific conductivity g, derived from FIG. 3, of sulfuric acid as a function of the temperature T for various no-load voltages U00 in an individual cell in the range from 1.9 to 2.15 V, as are produced for various acid concentrations. This clearly shows that the temperature-dependent specific conductivity g for the various no-load voltages U00 can in each case be represented approximately as linear functions.


There is thus a relatively simple and unique relationship between the specific conductivity g and the temperature T, as well as the no-load voltage U00, which describes the second function f(T,SOC) for determination of the second resistance component as a function of the parameters temperature T and state of charge SOC, and/or no-load voltage U00. The second resistance component RElyt is in this case calculated from a battery-dependent second factor Lfact and from this second battery-independent function f(T,SOC).


For a six-cell lead-acid rechargeable battery, the following approximations have been found for the first function r(T[° C.]) and f(t[° C.], U00 [V]):

r(T[° C.])=(l+0.00334·(T−25)] and
f(T[° C.])U00[V]=(1.2487·(U00−11.175)−0.4664·(U00−11.175)2)·(l+0.0137·(T−25)),

with the temperature T0=25° C. having been chosen as the reference point for the temperature relationships.


The first factor RfactMet and the second factor Lfact are parameters which characterize the energy storage battery. These values may either be specified by the battery manufacturer or may be learned during battery operation. Learning the first and second factors has the advantage that no prior knowledge is required about the battery type, the battery size, and the battery manufacturer.


These first and second factors RfactMet and Lfact and the equation

Ri=RfactMet(T0r(T)+l/(Lfact·f(T,SOC/U00))

can now be used to directly predict the internal resistance R for any given temperatures T and state of charge parameters SOC with the aid of the first and second functions r(T) and f(T,SOC). This has the advantage that the first and second functions r(T) and f(T,SOC) are relatively simple, unique, and, in particular, independent of the battery.


A method for determination of the first factor RfactMet and of the second factor Lfact will be explained in the following text.


The internal resistance R1, the battery or environmental temperature T1 and the no-load voltage U001 are measured in a first step. A value is then estimated for the first factor RfactMet(T0). The equation

Lfact=l/([R1−RfactMet(T0r(T)]·f(T,U00))  (1)

which is obtained from the equations described above is then used to calculate the second factor Lfact.


The estimated first factor RfactMet for the reference temperature T0 and the calculated second factor Lfact can now be used to make a first, still relatively inaccurate, prognosis of the future battery behavior in different environmental and/or battery state conditions.


In a next step, the internal resistance R2, the battery or environmental temperature T2 and the no-load voltage U002 are measured again with changed environmental and/or battery state conditions, for example with a different environmental or battery temperature T.


The following equation











Rfact
Met



(

T
0

)


=




R
1

·

f


(


T
1

,

U
001


)



-


R
2

·

f


(


T
2

,

U
002


)







r


(

T
1

)


·

f


(


T
1

,

U
001


)



-


r


(

T
2

)


·

f


(


T
2

,

U
002


)









(
2
)








is then used together with the two measurements that have been carried out to calculate an improved value of the first factor RfactMet(T0).


The associated second factor Lfact is then calculated using the equation (1) as mentioned above and the newly calculated first factor RfactMet(T0).


In order to improve the accuracy, the measurements and the substitution of the measurement results into equations (2) and (1) can be repeated as often as desired.


The first and second factors RfactMet and Lfact which characterize the energy storage battery can in this way be determined in a relatively simple manner, allowing quite accurate prediction of the internal resistance Ri in different environmental and battery states.


One feature for this iterative determination of the first and second factors RfactMet and Lfact is that the environmental and/or battery state conditions, such as the battery or environmental temperature T or state of charge, differ significantly from one another in the various measurements.


In order to take account of aging effects, the determination of the first and second factors RfactMet and Lfact should, for example, be repeated at intervals.


Since uncertainties must always be assumed, for example, relating to the measurement accuracy of the test equipment, and scatter must therefore be taken into account, the determined first and second factors RfactMet and Lfact should not be transferred directly. In fact, it is advantageous for the instantaneously determined factor to be correlated after having been weighted with a previously determined factor. For example, the first factor can be calculated using the equation

RfactMet(T0)=RfactMet1(T0)+(RfactMet0(T0)−RfactMet1(T0))·WEIGHT

and the second factor can be calculated using the formula

Lfact=(Lfact1+(Lfact0−Lfact1))·WEIGHT

with the index 1 denoting the factor determined from the instantaneous measurement and the index 0 denoting a factor determined from a previous measurement. The weighting factor WEIGHT should be chosen as a value between 0 and 1, depending on the reliability of the resistance determination. For example, the weighting factor should be chosen to be higher the less the measurement inaccuracy with respect to the battery voltage and the battery current i. For example, in the case of a current/time profile i(T), if a large number of associated value pairs Ui and Ii have been determined and it has been possible to calculate numerous internal resistance values RK from them, then a higher weighting factor can be associated with the factor RfactMet(T0) obtained from this than if the determination process were based on a single value pair for the voltage/current change. The weighting can likewise be chosen, for example, to be higher the greater extent that the temperature T or the state of charge parameters SOC differ from one another at the time of the measurements of the internal resistance Ri. An analogous situation applies to the second factor Lfact.


In this way, it is possible to learn the relationship between the internal resistance Ri of the energy storage battery and the state of charge for the temperature, even if the size and type of energy storage battery are not known. This is particularly advantageous in systems in which it is possible for the energy storage battery to be replaced by another energy storage battery which is not physically the same, or to be replaced by untrained personnel, for example, in a motor vehicle.


The method for learning the first and second factors also makes it possible to identify aging effects in the energy storage battery, for example, when the first and second factors RfactMet and Lfact are determined in a first operating period, in order to characterize the energy storage battery. If it is then found in a second operating period that the first and second factors RfactMet and Lfact remain approximately constant while, in a third period, it is found that the first and second factors RfactMet and Lfact change, in particular systematically, then it is possible to deduce that ageing has occurred.


The method for prediction of the internal resistance Ri can be associated with other methods which predict the operating behavior of the energy storage batteries in other states of charge SOC and/or at other temperatures T. For example, when using an electrical equivalent circuit which contains a pure resistive component, the predicted internal resistance Ri for assumed environmental and/or battery state conditions can be inserted into the equivalent circuit. It is then possible, for example, to use the equivalent circuit to predict the voltage response of the energy storage battery.


In addition to the first resistance component RMet and the second resistance component RElyt, further resistance components may also occur, although these are generally negligible in the case of a battery. By way of example, a third resistance component may be the electrical resistance of the energy storage battery for the region of the positive active masses, and a fourth resistance component may be the electrical resistance of the energy storage battery for the region of the negative active masses. These further resistance components generally likewise have their own characteristic dependence on the battery or environmental temperature and on the state of charge SOC of the energy storage battery. The third and fourth resistance components are significant in particular for lithium-ion batteries, and should thus be determined in a corresponding manner by means of a battery-dependent factor and a battery-independent function. In this case, the functional relationship between the associated factor and the environmental and battery state parameters is formulated, and the parameters are determined successively using assumed initial values and a minimum number of mutually independent measurements.


According to another exemplary embodiment, a monitoring device is provided for energy storage batteries that includes measurement means for measurement of parameters for the environmental and operating state conditions for the energy storage battery, and having computation means which are designed to carry out the method described above. The computation means may, for example, be in the form of a processor device with computer programs running on the processor device. The measurement means are preferably provided for measurement of the battery or environmental temperature, for determination of the internal resistance, and for measurement of the no-load voltage.


According to another exemplary embodiment, a product in the form of an embodied computer program is provided with program code means which are designed to carry out the method described above when the computer program is run using a processor device. The parameters for the environmental and battery state conditions, in particular the temperature, the measurement variables for determination of the state of charge parameters and the internal resistance are detected by the computer program, via suitable interfaces.


It is important to note that the method and systems described in the preferred and other exemplary embodiments are illustrative only. Although only a few embodiments of the present inventions have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in values of parameters, etc.) without materially departing from the novel teachings and advantages of the subject matter recited herein. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the preferred and other exemplary embodiments without departing from the scope of the present inventions.

Claims
  • 1. A method for predicting the internal resistance of an energy storage battery in assumed environmental and battery state conditions, the method comprising: subdividing the internal resistance into a first resistance component which represents the electrical resistance of the energy storage battery for the region of electron conduction and a second resistance component which represents the electrical resistance of the energy storage battery for the region of ion conduction;determining a first factor for the first resistance component and a second factor for the second resistance component as a function of the type of energy storage battery, wherein the first and second factors are determined by determining parameters and internal resistances for at least two conditions which differ from one another, wherein the at least two conditions are selected from environmental and battery state conditions; anddetermining the first and second resistance components to be expected for the assumed environmental and battery state conditions, wherein the first resistance component is determined from the first factor and from a battery-independent first function of parameters relating to the environmental conditions for the energy storage battery and the second resistance component is determined from the second factor and from a battery-independent second function relating to the environmental and battery state conditions for the energy storage battery.
  • 2. The method of claim 1 further comprising: utilizing a variable which is dependent on battery temperature as a parameter for determining the first resistance component; andutilizing a variable which is dependent on battery temperature and on the state of charge of the energy storage battery as a parameter for determining the second resistance component.
  • 3. The method of claim 2 further comprising: determining at least one of the battery temperature and the environmental temperature as a temperature parameter;determining the no-load voltage of the energy storage battery as a state of charge parameter; anddetermining the internal resistance of the energy storage battery.
  • 4. The method of claim 1 further comprising: a) estimating the first factor;b) determining the second factor as a function of the estimated first factor and of parameters which have been determined for first environmental and battery state conditions;c) determining a corrected first factor for second environmental conditions and battery state conditions as a function of the previously determined second factor and of the parameters determined for the second environmental and battery state conditions; andd) determining the second factor as a function of the corrected first factor and of the parameters determined for at least one of the first environmental conditions, the second environmental conditions, and the battery state conditions.
  • 5. The method of claim 4 further comprising repeating steps c) and d).
  • 6. The method of claim 1 wherein determining the first resistance component utilizes the formula RMet=RFactMet(T0)·r(T)where RMet is the first resistance component, RFactMet(T0) is the first factor for a reference temperature T0 and r(T) is a first function which is dependent on battery temperature T.
  • 7. The method of claim 6 wherein the first function is defined by the equation r(T)=l+k·(T−T0)+1(T−T0)2where k and l are constants.
  • 8. The method of claim 7 wherein determining the second resistance component utilizes the formula
  • 9. The method of claim 8 wherein the second function is defined by the equation f(T,SOC)=(a+b·SOC+c·SOC2)·(l +d(T−T0)+e (T−T0)2)where a, b, c, d and e are constants and T0 is a reference temperature.
  • 10. The method of claim 1 further comprising: determining an instantaneous first factor for instantaneous environmental and battery state conditions; andcalculating a corrected first factor from the instantaneous first factor and from at least one weighted previously determined first factor.
  • 11. The method of claim 10 further comprising: determining an instantaneous second factor for instantaneous environmental and battery state conditions; andcalculating a corrected second factor from the instantaneous second factor and from a weighted previously determined second factor.
  • 12. The method of claim 11 further comprising: calculating the first factor for the reference temperature utilizing the formula
  • 13. The method of claim 12 further comprising: calculating the second factor using the formula Lfact=l/([R1-RfactMet(T0)]·f(Ti, SOCi)where Lfact is the second factor, Ri is the internal resistance, Ti is one of the battery temperature and the environmental temperature, and SOC1 is the state of charge parameter at the time of a measurement i.
  • 14. The method of claim 1 further comprising: subdividing the internal resistance into a third resistance component for the region of the positive active mass of the energy storage battery and into a fourth resistance component for the region of the negative active mass of the energy storage battery; anddetermining the third and fourth resistance components in using an associated factor and a function of parameters for environmental and battery state conditions.
  • 15. The method of claim 1 further comprising predicting the state of the energy storage battery as a function of predicted internal resistance.
  • 16. The method of claim 15 further comprising predicting at least one of the wear, the performance, and the functionality of the energy storage battery.
  • 17. A monitoring device for an energy storage battery comprising: a measurement device for measuring parameters for the environmental and operating state conditions of the energy storage battery; anda computation device configured to carry out a method comprising: subdividing the internal resistance of the energy storage battery into a first resistance component which represents the electrical resistance of the energy storage battery for the region of electron conduction and a second resistance component which represents the electrical resistance of the energy storage battery for the region of ion conduction;determining a first factor for the first resistance component and a second factor for the second resistance component as a function of the type of energy storage battery, wherein the first and second factors are determined by determining parameters and internal resistances for at least two conditions which differ from one another, wherein the at least two conditions are selected from environmental and battery state conditions; anddetermining the first and second resistance components to be expected for the assumed environmental and battery state conditions, wherein the first resistance component is determined from the first factor and from a battery-independent first function of parameters relating to the environmental conditions for the energy storage battery and the second resistance component is determined from the second factor and from a battery-independent second function relating to the environmental and battery state conditions for the energy storage battery.
  • 18. The monitoring device of 17 wherein the measurement means are provided for measurement of at least one of the battery temperature and the environmental temperature, for determination of the internal resistance of the energy storage battery, and for measurement of the no-load voltage of the energy storage battery.
  • 19. A computer program comprising: computer program code that when run using a processor device is configured to carry out a method comprising: subdividing the internal resistance of the energy storage battery into a first resistance component which represents the electrical resistance of the energy storage battery for the region of electron conduction and a second resistance component which represents the electrical resistance of the energy storage battery for the region of ion conduction;determining a first factor for the first resistance component and a second factor for the second resistance component as a function of the type of energy storage battery, wherein the first and second factors are determined by determining parameters and internal resistances for at least two conditions which differ from one another, wherein the at least two conditions are selected from environmental and battery state conditions; anddetermining the first and second resistance components to be expected for the assumed environmental and battery state conditions, wherein the first resistance component is determined from the first factor and from a battery-independent first function of parameters relating to the environmental conditions for the energy storage battery and the second resistance component is determined from the second factor and from a battery-independent second function relating to the environmental and battery state conditions for the energy storage battery.
  • 20. The computer program of claim 19 wherein the computer program code comprises a program file which is stored on a data storage medium.
  • 21. The computer program of claim 19 wherein the computer program code comprises a program data stream that is transmitted in a data network.
Priority Claims (1)
Number Date Country Kind
102 52 760 Nov 2002 DE national
US Referenced Citations (112)
Number Name Date Kind
3906329 Bader Sep 1975 A
4153867 Jungfer et al. May 1979 A
4193025 Frailing et al. Mar 1980 A
4207611 Gordon Jun 1980 A
4322685 Frailing et al. Mar 1982 A
4595880 Patil Jun 1986 A
4642600 Gummelt et al. Feb 1987 A
4659977 Kissel et al. Apr 1987 A
4665370 Holland May 1987 A
4719427 Morishita et al. Jan 1988 A
4816736 Dougherty et al. Mar 1989 A
4876513 Brilmyer et al. Oct 1989 A
4888716 Ueno Dec 1989 A
4937528 Palanisamy Jun 1990 A
4943777 Nakamura et al. Jul 1990 A
4952861 Horn Aug 1990 A
5002840 Klebenow et al. Mar 1991 A
5032825 Kuznicki Jul 1991 A
5055656 Farah et al. Oct 1991 A
5079716 Lenhardt et al. Jan 1992 A
5130699 Reher et al. Jul 1992 A
5159272 Rao et al. Oct 1992 A
5162164 Dougherty et al. Nov 1992 A
5204610 Pierson et al. Apr 1993 A
5223351 Wruck Jun 1993 A
5280231 Kato et al. Jan 1994 A
5281919 Palanisamy Jan 1994 A
5316868 Dougherty et al. May 1994 A
5321627 Reher Jun 1994 A
5352968 Reni et al. Oct 1994 A
5381096 Hirzel Jan 1995 A
5404129 Novak et al. Apr 1995 A
5412323 Kato et al. May 1995 A
5416402 Reher et al. May 1995 A
5421009 Platt May 1995 A
5428560 Leon et al. Jun 1995 A
5439577 Weres et al. Aug 1995 A
5488283 Dougherty et al. Jan 1996 A
5549984 Dougherty Aug 1996 A
5552642 Dougherty et al. Sep 1996 A
5563496 McClure Oct 1996 A
5572136 Champlin Nov 1996 A
5578915 Crouch, Jr. et al. Nov 1996 A
5656915 Eaves Aug 1997 A
5680050 Kawai et al. Oct 1997 A
5698965 York Dec 1997 A
5721688 Bramwell Feb 1998 A
5744936 Kawakami Apr 1998 A
5744963 Arai et al. Apr 1998 A
5761072 Bardsley, Jr. et al. Jun 1998 A
5773977 Dougherty Jun 1998 A
5808367 Akagi et al. Sep 1998 A
5808445 Aylor et al. Sep 1998 A
5818116 Nakae et al. Oct 1998 A
5818333 Yaffe et al. Oct 1998 A
5896023 Richter Apr 1999 A
5898292 Takemoto et al. Apr 1999 A
5936383 Ng et al. Aug 1999 A
5965954 Johnson et al. Oct 1999 A
5977654 Johnson et al. Nov 1999 A
5990660 Meissner Nov 1999 A
6016047 Notten et al. Jan 2000 A
6037749 Parsonage Mar 2000 A
6037777 Champlin Mar 2000 A
6057666 Dougherty et al. May 2000 A
6087808 Pritchard Jul 2000 A
6091325 Zur et al. Jul 2000 A
6118252 Richter Sep 2000 A
6118275 Yoon et al. Sep 2000 A
6144185 Dougherty et al. Nov 2000 A
6160382 Yoon et al. Dec 2000 A
6163133 Laig-Horstebrock et al. Dec 2000 A
6167349 Alvarez Dec 2000 A
6222341 Dougherty et al. Apr 2001 B1
6268712 Laig-Horstebrock et al. Jul 2001 B1
6271642 Dougherty et al. Aug 2001 B1
6296593 Gotou et al. Oct 2001 B1
6300763 Kwok Oct 2001 B1
6304059 Chalasani et al. Oct 2001 B1
6331762 Bertness Dec 2001 B1
6369578 Crouch, Jr. et al. Apr 2002 B1
6388421 Abe May 2002 B1
6388450 Richter et al. May 2002 B1
6392389 Kohler May 2002 B1
6392414 Bertness May 2002 B1
6392415 Laig-Horstebrock et al. May 2002 B1
6417668 Howard et al. Jul 2002 B1
6424157 Gollomp et al. Jul 2002 B1
6441585 Bertness Aug 2002 B1
6445158 Bertness et al. Sep 2002 B1
6452361 Dougherty et al. Sep 2002 B1
6472875 Meyer Oct 2002 B1
6495990 Champlin Dec 2002 B1
6507194 Suzuki Jan 2003 B1
6515452 Choo Feb 2003 B1
6515456 Mixon Feb 2003 B1
6522148 Ochiai et al. Feb 2003 B1
6534992 Meissner et al. Mar 2003 B1
6556019 Bertness Apr 2003 B1
6600237 Meissner Jul 2003 B1
6600293 Kikuchi Jul 2003 B1
6608482 Sakai et al. Aug 2003 B1
6653818 Laig-Horstebrock et al. Nov 2003 B1
20020008495 Dougherty et al. Jan 2002 A1
20020026252 Wruck et al. Feb 2002 A1
20020031700 Wruck et al. Mar 2002 A1
20030047366 Andrew et al. Mar 2003 A1
20030082440 Mrotek et al. May 2003 A1
20030142228 Flach et al. Jul 2003 A1
20030236656 Dougherty Dec 2003 A1
20040021468 Dougherty et al. Feb 2004 A1
20040212367 Dougherty Oct 2004 A1
Foreign Referenced Citations (32)
Number Date Country
22 42 410 Mar 1973 DE
2 242 510 Apr 1974 DE
25 11 426 Sep 1975 DE
33 34 128 Apr 1985 DE
37 12 629 Oct 1987 DE
38 08 559 Sep 1989 DE
39 01 680 Mar 1990 DE
40 07 883 Sep 1991 DE
38 82 374 Oct 1993 DE
44 14 134 Nov 1994 DE
43 39 568 May 1995 DE
689 24 169 Mar 1996 DE
195 40 827 May 1996 DE
195 43 874 May 1996 DE
197 50 309 May 1999 DE
691 31 276 Dec 1999 DE
694 23 918 Aug 2000 DE
199 52 693 May 2001 DE
199 60 761 May 2001 DE
93 21 638 Aug 2001 DE
100 21 161 Oct 2001 DE
69900638 Mar 2002 DE
699 00 638 Aug 2002 DE
0 516 336 Feb 1992 EP
1 116 958 Jul 2001 EP
1 120 641 Aug 2001 EP
WO 9715839 May 1997 WO
WO 99 17128 Apr 1999 WO
WO 99 66340 Dec 1999 WO
WO 0004620 Jan 2000 WO
WO 01 15023 Mar 2001 WO
WO 03001224 Jan 2003 WO
Related Publications (1)
Number Date Country
20040150406 A1 Aug 2004 US