DE4014737A1 - Physical value determn. for accumulator - measures process input values of energy storage which are processed in computer - Google Patents

Abstract

The process input variables (I,t,Taccu, Tamb; U(t)) are measured and are processed in a computer. The specified model is arranged in the form of closed linear or non-linear multi-parametric functions and/or heuristic parametrised as an evaluation which represents the physical variables to be determined and their physical relationships to each other. The evaluation or evaluations are compared to the measured process input variables and for the subsequent measurement the model and/or the evaluation is adapted. The voltage measured with a charging or discharging operation (U(t)) is compared wtih the model output value (U'(t)) and the voltage different is monitored. USE/ADVANTAGE - Method and unit for determining physical variables of rechargeable electrical storages e.g. accumulators. Enables continuous, unambiguous monitoring of accumulator related to specific programme in computer.

Description

1. Field of application

The invention relates to a method for determining physical quantities of rechargeable electrical Energy storage and device for carrying out of the procedure.

Rechargeable (reversible) electrical energy storage are used in a lot of areas today to operate electrical devices independently of the mains to guarantee. The most widespread at the moment Types are lead batteries, nickel-cadmium batteries, sodium Sulfur batteries and lithium fluorine batteries. Next you bring many advantages associated with it Use also problems with it, e.g. B. the higher cost and the maintenance effort, but mainly the  limited energy supply. But now the fact that the extractable energy is finite and the one used Battery replaced or recharged at some point must be to get over as such. The real difficulty is that one often do not know when this will be d. H. how long you operate his device with the currently used battery can or how much energy / charge is still in the Battery is located.

In some areas of application these are limitations only annoying or expensive; in many cases but they also lead to the fact that the use of Batteries is dispensed with. It usually becomes non-reversible polluting primary cells used from a certain consumption (Number of cycles) are more expensive and extremely polluting, but less problems with the charge information because of the advanced discharge noticeable in time by a drop in tension makes. The security-relevant areas such as medicine, Traffic, fire brigades, etc. are in the first place name, but also many hobby applications (e.g. Diving, mountaineering, model building) open up the battery insert only slowly or not at all.

The reason for this lies in the behavior of most rechargeable batteries, as shown in Fig. 1 using the example of the widely used NiCd battery:
Before the sudden and steep voltage drop shortly before the complete discharge, a long phase with almost constant voltage can be seen; during approx. 90% of the discharge time (with constant current) the voltage changes only by less than 10%. This property is initially a favorable prerequisite, because an almost constant voltage during almost the entire operating time of the battery ensures the full performance of the device during this time. On the other hand, however, point C in the discharge curve shown, namely the point at which recharging must take place at the latest, can only be recognized at a point in time when only considerably less than 10% of the total charge is available and the voltage supply afterwards very soon collapses.

The only sizes measurable without tampering with the battery are amperage and temperature caused by the environment be specified, and the tension that is present in these Conditions on the electrodes of the battery. The nominal voltage of a battery depends on the age and of characteristics of the battery, that of the specimen scatter subject to. Because the voltage change in the main part of the unloading process in the same order of magnitude as moves the mentioned spread of the nominal voltage, the Voltage alone is a very bad measure of the charge / Display the energy content of the battery. For the Systems are therefore necessary to determine the state of charge, the required from the measurable sizes Derive information.

2. State of the art

In the previously known methods of state of charge monitoring, the easily measurable quantities of the process are recorded (I, T, U, t) , the loading / unloading is balanced from the beginning of the process and used with the help of physical formulas to estimate the state of charge (DE -PS 34 29 145).

None of the known methods have been for use can prevail in practical use. The The reasons for this lie in the unsatisfactory Accuracy of measurement and that for sensible use Boundary conditions to be observed:

• - The state of charge monitoring process must be carried out with the known methods / devices with a new battery be started; with already used batteries so far not possible. Especially with NiCd cells it often happens that batteries with unknown Prehistory can be used. Monitoring goes here in almost all cases of incorrect starting data off, the determination of the available capacity must therefore to be wrong.
• - During the life of the battery, the voltage do not go to zero, otherwise the monitoring unit loses her memory and after recharging incorrectly assumes a new battery.
• - But even with full compliance with the required Framework is still not a satisfactory one Measurement accuracy guaranteed. Because it is for the indirect determination of the state of charge from the easily measurable sizes from the table Dependencies. However, neither  the individual manufacturing tolerances are still and type-specific differences are taken into account.

The object of the invention is therefore a method for determination of physical sizes of rechargeable electrical energy storage and device for carrying out of the method, the process input variables of the energy store measured and processed in a computer be designed to the effect that even with energy storage with unknown state of charge and history, a reliable statement about the available capacity as well Age and efficiency is made possible.

According to the invention, this object is achieved by the method Claim 1 solved. Advantageous refinements of the method are shown in the subclaims. Devices to carry out the method are in claims 11 and 12 specified.

An introduction to the principle of measuring with an observer is from IEEE Transactions on Automatic Control vol. AC-16 No 6 Dec 71, pages 596-602, "Introduction to Observers" by David G. Luenberger, known or from IEEE Transactions on Military, Electronics Vol. 7, 1963, David Luenberger: "Observing the State of a Linear System ", page 74-80, Prof. Zeitz Michael, Bochum, "Nonlinear Observer ...", VDI-Verlag, progress reports VDIZ, row 8, no.27.

Indirect measurement with models provides results, that are not directly measurable. The comparison of these sizes with the real values of the process is at best one later point in time (e.g. when fully discharged) possible. Before that, however, influences not recorded can  change the process so that an initially undetectable one Measurement errors arise with the indirectly measured size.

If one measures a voltage in the central one at the electrodes Working area of the battery, so are from it - not even with the knowledge of a closed model - hardly any statements derivable about the state of charge of the battery, if you use it Battery classes has to do with a flat characteristic of tension.

Only when two essential properties are known is the Voltage is a significant feature of the state of charge; this are individual scatter and the state of aging. The changes in the voltage resulting from this lie in the same Order of magnitude like those resulting from the change the state of charge.

An indirect measurement e.g. B. according to DE-OS 37 36 481 goes from one new battery or from a battery of known age as well from the catalog values for individual energy storage out. Individual deviations from the catalog values will be just as little taken into account as deviations from the assumed Age from the actual state of wear.

The result is a statement about the state of charge of the Batteries that deviate very much from reality in extreme cases, without the measuring system being aware of this deviation Feedback is given.  

This effect is avoided with the methods according to the invention. The invention will now be explained in more detail below will.

3. Presentation of the invention 3.1. Measure and watch

A model-based simulation runs parallel to the loading / unloading process (process), to which the same process input variables as the process are fed. The easily measurable process output variables, in this case the voltage U (t) , are compared with the corresponding values from the model. The current model parameters are then adjusted in order to minimize the deviation between real and modeled process output variables. This leads to the following advantageous properties of the measuring system, which is also referred to below as the monitor:

• a) It takes place by constantly going through the observer cycle the system always adapts itself, the all manufacturer, type and battery-specific variations Takes into account.
• b) Batteries with an unknown history can be used with the known type data as start values serve in the adaptation.
• c) After data loss due to voltage zero crossing the system can take a new approach.
• d) The adjustment is made automatically to the current one  Characteristic curve of the accumulator. All influences by the internal and external process conditions are taken into account.
• e) The observer starts with predetermined values, e.g. B. Catalog or literature values, as a 0 th order model. With each adaptation cycle, they improve current model parameters.

Fig. 2 shows the adaptation cycle based on the observer principle:

The easily measurable process input variables ( 1 ), the current, the time, the temperature of the battery and that of the environment influence the real process of loading or unloading ( 2 ) and are simultaneously measured by the monitoring system ( 3 ).

The process now has its output variables at any time, some of which can be measured, in this case the voltage U (t) ( 4 ), but some of which remains hidden from the direct measurement ( 5 ). These are essentially the amount of charge that can be removed (Q (t) and the differential charging efficiency η _L (t).

Parallel to the real process, a model calculation is carried out ( 6 ), in which the process input variables originating from the measurement are based on model equations ( 7 ) and the associated model parameters ( 8 ) of the current process state for calculating the process output -Sizes corresponding model output sizes Größen (t) ( 9 ) and (t) and η _L (t) ( 10 ) can be used.

The model output variables ( 10 ) corresponding to the non-measurable process output variables cannot be compared with their corresponding variables. This only happens with the model output value corresponding to the voltage.

In a deterministic, closed model, the agreement of the two voltage values is equivalent to the agreement of the other quantities if all parameters appear in the model equations for the voltage. It is then sufficient to minimize the deviation of the two voltage values ( 11 ) in order to find a correct image of the process for the quantities specified in ( 10 ).

For this purpose, the set of model parameters becomes new from the voltage difference ( 12 ) together with the measured values from ( 3 ) and the model properties (equations and parameters, ( 7 ) and ( 8 )) in the sense of minimizing the voltage difference ( 13 ) calculated and thus adapted to the current process state ( 14 ).

The model calculation ( 6 ) is then carried out again with the new parameters. The quantities ( 10 ) calculated are the result of the indirect measurement.

3.3. Heuristic parameter adjustment

The described cycle of observers must have models in the form closed functions, such as B. equations according to the Peukert type or multi-parameter functions  lie. These functions can be linear or non-linear be.

The more closed specifiable model equations the system describe, the smaller the set of possible solution vectors becomes.

A clear solution to the adaptation only exists if the model functions just so many open parameters contain, like process variables coming into the model equations can be measured directly.

In practice, however, it is usually the case that a system is undetermined and there are always classes of possible solutions exist that represent themselves as subspaces of the solution vector space to let.

In extreme cases, there are no closed model equations at all specifiable, which leads to that first of all all solution vectors in the parameter space in deterministic Senses are equivalent.

That is e.g. B. the case when of an energy storage device Characteristic curve, age and efficiency are unknown, the available capacity should be measured.

However, it looks different if you look at the possible solution vectors viewed with the help of prior knowledge. This prior knowledge initially only contains the experience knowledge about the treated battery class in general (e.g. NiCd battery, lead battery, sodium battery) and via the Battery type in particular (manufacturer, size, nominal parameters) and is composed of those known with regard to the process Rules and the associated facts (data).

You also know individual data of the present  the batteries or already measured values from the currently running Process, this information can also be made using specific Guidelines used to estimate system health will.

As with measuring using the observer principle, after each Measuring process the process output variables, in this case the Tension, with the corresponding sizes of the model compared and in the case of deviations using a rule-based Adaptation algorithm adapted. An easy Reinforcing (or steaming) or adjusting in one simple control loop (e.g. PID controller with a time constant significantly smaller than the sampling cycle duration) not out for this purpose. You did that primary goal - namely to minimize the current deviation -, but the parameters would not be regarding checks the plausibility criteria that result from based on experience.

In contrast, every step in the iterative is rule-based Parameter estimation the entire previous knowledge from the present process and only in the case of a plausible one Parameter configuration is returned to the waiting state, only after new measured values are available is left again.

Under certain conditions (such as larger deviations between two measuring cycles) it may be necessary the real characteristic traversed so far again Plausibility with regard to the newly estimated parameters check ("backward tracing"). It is similar with the process course to be expected in the future; he too must  then checked for plausibility ("forward tracing") and only with a reasonable result of both branches the parameters declared plausible.

If there is none for the current process configuration plausible parameter set based on those from the last measurement cycle, is the so-called Apply "backtracking". For this, be in regular Intervals the measured and parameter values are buffered, to be able to use these values afterwards. From there, an attempt is made again, taking into account the process information on the meantime on a rather plausible parameter configuration at the current working point to get.

In certain situations (such as outside disturbances or in the event of high current discharges), a premature one Recalibration process may be required. This will by default only at the "corner points", i.e. H. when switching loading and unloading and vice versa.

During this recalibration, those parameters are adjusted which usually change little and under certain requirements (in the case of full or total discharge) compared with the corresponding sizes of the process can be. This comparison option is not available or one arrives despite using all of the methods described no longer one reasonable parameter constellation, these parameters must from the knowledge accumulated up to this point to be appreciated.  

The procedure for heuristic parameter adjustment is shown schematically in Fig. 3. Steps 1 to 5 correspond to those in Fig. 2.

In contrast to measuring with the observer principle, however, no model calculation can take place because there is no closed system of equations for linking the measured variables from ( 3 ). The arithmetically determined process output variables ( 9 ) and ( 10 ) are instead estimated according to rules ( 15 ) based on experience, together with the data on the individual battery ( 16 ) known up to this point ( 17 ). Then the newly added data ( 9 ), ( 10 ), ( 11 ) and ( 12 ) are entered in the database ( 16 ) and a series of plausibility checks are carried out with the new constellation ( 18 ). If these tests lead to an intolerable contradiction with experience at one point, a re-estimation is carried out, possibly using one of the methods described above ( 17 ). This estimation cycle is repeated - still on the basis of a single new measurement - until a plausible parameter constellation has been found ( 19 ) that cannot be improved further. This then applies until the next measurement ( 3 ).

The case that no plausible parameter constellation was found is not provided. With a suitable rule set this can be excluded. So z. B. after the insertion of a previously unknown battery and the No parameter set found when performing the first measurement who is as plausible in all respects as the one in the case of a battery in which the last 50 and discharge cycles were logged in the same device.  

The acceptance of the nominal sizes from the catalog As long as the table for a new battery is considered plausible, until the measurement data indicate something else.

So there are tolerance areas for the plausibility checks for the parameter constellation that is to be expected Let errors in the measured value close. Because over time so the longer the monitor and battery work together, the Tolerance fields for the parameters are getting narrower thus also an improvement in the quality of the measured values of the monitor connected.

3.3 Combinations of processes

Determining the state of charge of a reversible electrical Energy storage can, as described above, by means of indirect measurement via models achieved by two methods the adaptation of the parameters using the observer principle and with heuristic methods. Both approaches are on both branches, the loading and unloading branch of the Characteristic curve, applicable and describe on deterministic or heuristically the loading and unloading behavior of the Accumulator.

Both sub-branches already enable that Extract detailed information about the current Battery parameter. Every process for itself, but also arbitrary Combinations are for use in one version of the Monitors conceivable. This can therefore be executed as component

• a) only the charger
• b) only the consumer device
• c) the battery

solution combinations and mixed forms are also possible are.

3.4 Model approaches

The methods described in 3.1 and 3.2 represent ideal cases both of which are practically non-existent in real batteries. Neither the case that a battery pack in its entirety Work area closed depending on all state variables is completely writable, a complete lack of model-like functional relationships come from one of the common types to wear. Therefore, the model approaches mostly deal with combinations of deterministic and phenomenological functions as well heuristic components. Using the example of the NiCd battery outlined below what types of equations are used can be.

3.1 Loading model

The charging voltage of the NiCd battery can be determined from the Butler-Volmer equation derived deterministic approach for the breakdown voltage and a phenomenological Approach for the differential voltage can be represented as:  

With the exception of the loading current I _B and the state of charge L, all quantities on the right side of the equation are suitable constants or model parameters (e.g. u _D , U _ZG Z, f) .

P (L) is a polynomial that is determined by numerical approximation from measured characteristic curves. The load current can be measured directly; the current state of charge can be determined from the balance of the amount of charge loaded if one knows the differential charging efficiency h _L. This is defined as the removable amount of charge resulting from a charge storage:

The differential charging efficiency is from the loading current and depending on the current state of charge, considering this dependency also represented by a phenomenological approach can:

η L (L, I _B ) = e ^{Pm (L)} · I _B + P _{η L} ₀ (L) (3.3)

P _m (L) and P _{h L} ₀ (L) are polynomials (order approx. N = 5).

With the known differential charge efficiency the actually available amount of cargo from the stored Balance charge quantity:

and thus the modeled voltage value according to (3.1) can be given will.

So much for the mixed deterministic and phenomenological Model approach for the charging voltage of the NiCd battery.

If, for example, an unknown NiCd battery is now inserted in a charger with a monitor function and the voltage U (t) and the current I (t) are measured at its terminals, the modeled voltage U _B (t) according to (3.1) only matches the measured voltage if it is a

• - new
• - to empty
• - not subject to specimen distribution

NiCd battery. In all other cases there is one  Voltage difference, for the compensation of which there is first of all gives the possibility of approx. 20 parameters of equations 3.1 and 3.3 to change. You can find any number of vectors in this parameter space, which ensure that the voltage difference disappears. To make reasonable from these vectors to choose, be z. B. called the following rule.

According to the approach of the monitor function, a empty battery, unless otherwise known is. But is now only half of the battery used discharged, a much greater voltage arises, than the model predicts assuming an empty battery. It is now the most obvious for the monitor, the Reject the assumption that the battery is empty. The rule could be formulated as:

Rule 1

When a battery is inserted and no further information is available and the voltage at the terminals is too high then the battery is most likely not empty, so assume a higher charge level.

Before the next measuring cycle, it will now be zero assumed state of charge z. B. by means of a PID control characteristic increased so that the error, i.e. H. the voltage difference gets smaller. After a few measuring cycles it will System have adapted and the voltage difference will have become very small. But now the assumption  the battery is new and just happens to hit it Catalog values with their parameters, quite wrong be. In this case the state of charge is now assumed too large. This error can be read from the characteristics of the characteristic after going through a series of measuring cycles has been. Are the characteristics of the real measured Curve can only poorly match those of the model a renewed estimate of individual nominal capacity (the depends on the age and the number of specimens) and the model characteristic curve from the time of the model approach recalculated up to the working point and again can be compared with the real characteristic. Here results a different, inevitably smaller charge level. The valued and plausible individual Nominal capacity initially corresponds to a set of Solution vectors from the two-dimensional space of the conceivable Wear and tear and conditions caused by specimen scatter Fluctuation of this size as long as there is no evidence of that Limiting this amount there.

Rule 2 can therefore be applied if there is already a part the loading characteristic was passed:  

Rule 2

If rule 1 was applied and the characteristics of the characteristic curve do not match well, then the accepted individual is correct Nominal capacity not, So adjust individual nominal capacity so that

• a) a plausible characteristic curve arises,
• b) voltage difference below the then assumed loading capacity minimal becomes.

The characteristic curve is based on easily extractable Features compared such as curvature, slope, absolute value and integral (extracted energy).

3.4.2 Unloading model

The course of the discharge characteristic shows three clearly from each other definable areas:

• 1) A rapid drop at the start of the discharge
• 2) A long, almost linear drop with little pitch  
• 3) A sudden, steep drop

The model approach therefore consists of a linear (more precisely: affine) main part, the beginning and end of each an exponential function is superimposed.

The components are used as initial, linear and final parts are referred to and are formulated as follows:

Similar to 3.4.1 after inserting an unknown Battery initially from the normal values of a fully charged one Copy ran out.  

Now the initial parameters cannot be adapted directly to the size of interest, namely the current charge at the start of the final.

However, the parameters taken from the initial course leave an improved estimate of the course of the final. Even better this estimate is evaluated even if the linear part could be and the best is the course of the final predictable if the system takes this course at the could notice last discharge.

The following two rules are for conditional derivation of information from the measured values mentioned as an example.

Rule 3

If the beginning of the linear range typical of a semi-worn Battery is and no other information is available, then the battery is most likely half worn out.

Rule 4

If the beginning of the linear range typical of a semi-worn Battery is and the battery in the last cycle only as one Quarter worn out and there are no extraordinary incidents in progress Cycle gave then the battery is most likely only a little more than a quarter worn out.  

The numerical values and terms like "most likely" are, for example, statements that are actually going on Program by numbers, d. H. Probability values. Wear numbers etc., to be replaced. These numbers are type-specific; it is meant to be exemplary only in these simple rules be represented as the results of measurements with the previous knowledge.

Embodiments

There are different versions of devices to implement the described method. The restrictions are doing that with pure chargers (in the the battery is inserted in any condition and usually is removed fully loaded) only the loading branch, and vice versa with a pure consumer device (in which a full Battery inserted and removed empty) only the discharge branch can be evaluated.

When using the monitor as part of the battery or A battery package supports the evaluation of both branches. The same goes for consumer devices that use the battery for charging does not leave. It only plays one subordinate role, whether the battery is soldered or light is changeable. When using unknown batteries arise only longer adaptation phases until the set maximum achievable measurement accuracy.  

But also when using the monitor functions in the devices corresponding to the respective characteristic branch it is possible to evaluate both courses if the Battery its current information on a semiconductor memory (RAM or EEPROM) and this the notifies each other of the device. Even if only one of the two Devices has the monitor, this will make the Advantage created that the monitor over the current characteristic to the results from previous characteristic curve evaluations can fall back on this battery.

Overall, the following are shown Realization forms of the monitor.

1. The monitor is only part of the charger

The state-of-charge monitoring system is a device which is permanently assigned to the charger for carrying out the methods described under 3.1 and 3.2. Fig. 4 shows a block diagram of such a device, in which the individual components are listed and their respective interaction is indicated by arrows. The central component of this discrete structure is a microprocessor ( 21 ), which as an 8-bit microcomputer is equally inexpensive and space-saving and on the other hand has all the necessary performance features for this application. A 32-bit computer can also be used if the required accuracy and speed are required.

From the charger 28 with a display unit, the monitor ( 21, 23, 24, 25, 26, 27, 30, 31 ) = ( 37 ) receives a RESET pulse ( 22 ) in addition to its supply voltage after the battery ( 33 ) has been inserted and the Loading was started. The time base is set by a clock generator ( 23 ), which can be designed as a quartz or an electronic resonant circuit and, in addition to the CPU clock, also provides the timer clock by means of a CTC counter timer circuit ( 24 ), which ensures the interrupts the measured value recording is generated. This is carried out by an analog-to-digital converter ( 25 ), which sends the measurement signal selected by a multiplexer ( 26 ) in digitized form to the CPU ( 21 ).

The computer selects the input signal via an I / O module ( 27 ), which is also used for outputting the digital result to the charger ( 28 ) and, if necessary, for communication with the battery memory ( 29 ).

Programs and battery or device-specific data are stored on the system on a non-volatile semiconductor memory (ROM, PROM, EPROM, EEPROM,) ( 30 ). This module is the only one that has to be changed when the system is transferred to another carrier. A volatile memory (SRAM, DRAM) ( 31 ) is also required for the program execution or infeed.

In addition to the display mentioned, a temperature sensor ( 32 ) on the battery ( 33 ), a sensor for the ambient temperature ( 34 ) and a current sensor ( 35 ) must be installed on the charger ( 28 ). This can e.g. B. be designed as a Hall sensor in order to influence the process as little as possible. The input signal for the voltage is tapped at the active terminals of the charger by means of a sensor ( 36 ).

2. The monitor is only part of the consumer device

This structure corresponds to the diagram shown in Fig. 5; As with the charger, the monitor can be operated with and without the storage device on the battery.

3. The monitor is part of the battery

You can do without any interface and data transfer, if the monitor is an integral part of the battery or one Is battery packs. Both loading and unloading branches evaluated and all monitor functions optimally used. All Battery data are saved individually from the start and can by using a non-volatile Storage also preserved across the voltage zero crossing stay. This data preservation is not for the Functionality of the system required, even if data is lost a new adjustment takes place, however a Avoided increasing the error intervals with a new adaptation start with the unknown one Battery goes hand in hand.

4. The monitor is a consumer device and charger distributed system, the battery on a memory get their current data.

The full use of all monitor functions is also guaranteed if the charger and consumer device each have a device as shown in Fig. 4 and the battery carries its information in a permanently connected, non-volatile semiconductor memory so that it can always be put back on the other device of the monitoring process. In the case of volatile memory, the error statements mentioned above apply accordingly.

5. The monitor is called ASIC with various programs realized for all applications 1-4

To z. B. to be able to manufacture large quantities at low cost, or to accommodate the monitor in a confined space enable, the device can also be a highly integrated Block (ASIC) are executed.

To if possible in all implementation forms according to 1 to 4 To be able to be used, the building block must all required programs are given, each one Receive consecutive numbers from which you can select them can.

Fig. 5 shows schematically a structure in which the components located in Fig. 4 within the frame ( 37 ) can be used as macros for the structure of the highly integrated module ( 38 ). The carrier device transfers a four-digit binary program number ( 39) to the chip, which selects the entry point in the monitor program to which the program is to be jumped after the RESET ( 22 ). The functionality then corresponds to the respective discrete structure specified for this task.

The measured values which supply the loading / unloading characteristic are thus passed on from component ( 38 ) to memory ( 29 ) or requested by the latter. With knowledge of the manufacturer and thus the data of the energy store, these can be entered via a program input ( 39 ), larger error intervals are thus avoided.

The four-digit binary result (if necessary also with a longer word length) is transferred to the carrier device ( 40 ) via pins 16 - 19 .

List of symbols

f Abbreviation for F / R / T
I current
I ₀ basic current
I _B loading current
m _UE1 slope of the linear part of the discharge voltage
Q _B Load (loading)
Q _E Charge removed
U _Ef final part of the discharge voltage
U _Ei initial part of the discharge voltage
U _El linear part of the discharge voltage
U _El ₀ linear basic voltage
U _ZG cell equilibrium voltage
z valency
α penetration factor
η L Differential charging efficiency

Claims (16)

1. A method for determining physical quantities of rechargeable electrical energy stores, the process input quantities of the energy store (I, t, T _battery , T _environment ; U (t)) being measured and processed in a computer, characterized in that according to the known principle of indirect measurement, a predeterminable model, in the form of closed linear or nonlinear multi-parameter functions and / or a heuristic parameterization as an estimate, which represents the physical quantities to be determined and their physical relationships to one another, are compared with the measured process input quantities and for the subsequent ones Measuring the model and / or the estimate is adapted. 2. The method according to claim 1, characterized, that the physical quantities to be determined are the on the distribution of specimens and / or the state of aging dependent individual battery parameters and the are currently available loading capacity.   3. The method according to claims 1-2, characterized in that the voltage U (t) measured during loading / unloading is compared with the model output variable Û (t) and the voltage difference is monitored. 4. The method according to claim 3, characterized in that to minimize the voltage difference Δ U (t), the model parameters are recalculated one or more times for the subsequent measurement using the model equations and the measured process input variables. 5. The method according to claims 1-4, characterized, that from the measured process input variables and Using the same measurement assigned Model equations and model parameters the new model is calculated.   6. The method according to claim 5, characterized in that the model output variables Û (t) and (t) and (t) are determined from the model. 7. The method according to claim 1, characterized in that the new estimate is calculated from the measured process input variables and use of the rules and data associated with the same measurement, and the estimated output variables Û (t) and (t) and are determined therefrom. 8. The method according to claim 7, characterized, that a plausibility check of the new Parameter estimation is performed.   9. The method according to claim 8, characterized, that the plausibility check of the new parameters for previous and future measurements is carried out and then a comparison of the estimated with the measured values is carried out several times. 10. The method according to claims 8 and 9, characterized, that the measured values and parameter values be cached. 11. The method according to claim 1, characterized, that the model as an observer in the form of closed linear and / or non-linear multi-parameter Differential equations is selected.   12. An apparatus for performing the method according to claims 1-11 with a measuring device for measuring the process input variables of the energy store and a computer and memory, which carry out a comparison of the process input variables with stored data, characterized in that the monitor 37 from a microprocessor 21 , to which the process input variables are fed via a multiplexer 26 and downstream A / D converter ( 25 ), and which receives the time base from a clock generator 23 and assigned timer counter circuit 24 for the generation of the time intervals for the measurement value acquisition, the microprocessor continuing to exist is connected to an input / output unit 27 , which in turn is connected to the memory 29 of the rechargeable battery 33 and the multiplexer 26 and the charger 28 , and has memories 30, 31 for receiving the programs and data of the energy stores. 13. The apparatus according to claim 12, characterized in that the monitor 37 is part of the battery 33 . 14. The apparatus according to claim 12, characterized in that the monitor 37 is part of a charger and / or a consumer. 15. The apparatus according to claim 14, characterized in that the battery 33 has its own memory 29 , for. B. has a RAM or an EEPROM with an interface to the charger / consumer device. 16. Device according to claims 12-15, characterized in that the monitor is an integrated module 38 .