DE10312591A1 - Charging method for rechargeable battery involves controlling charging process for battery depending on time point of next use of battery and/or load state for next use of battery - Google Patents

Abstract

The charging method involves controlling the charging process for the battery depending on the time point (tNutz) of a next use of the battery and/or the load state for a next use of the battery. The charging process is additionally controlled depending on the operating temperature. The charging efficiency is significantly reduced just before the next use of the battery.

Description

The present invention relates to a charging process for a rechargeable battery and especially an energy efficient one and life-saving charging process for rechargeable batteries of electric and hybrid vehicles.

Charging process for rechargeable batteries are common dependent on on the battery temperature and / or the current state of charge Battery controlled. The loading process generally ends when when the battery is fully charged; for this are for different Battery systems known different termination criteria.

It is generally known that the charging efficiency η in the case of alkaline battery systems (e.g. NiCd, NiMH) for the charging process, depending on the battery temperature, significantly decreases with a state of charge SOC (state of charge) of the battery above a state of charge of about 75% ; the unsaved energy is essentially lost in the form of heat. 2 shows schematically the ampere efficiency η _{Ah of} an alkaline battery system depending on the state of charge SOC and the battery temperature. The energy efficiency η _Wh (in watt-hours), which also contains the time-variable voltage, which is dependent on the charging current and battery parameters, is in any case even lower than that in 2 Amp-hour efficiency shown η _Ah . This behavior can also be observed in other battery systems such as lead acid batteries, albeit less pronounced.

Furthermore, it is known that the self-discharge rate K increases significantly, depending on the battery temperature, in charge states SOC of more than about 95%, as schematically in FIG 3 shown. In the first hour after a full charge has taken place, the self-discharge rate K for an alkaline battery system, if the battery is not used during this period or is no longer charged, is of the order of magnitude of approximately 5% to 10% of the nominal capacity of the battery.

Furthermore, it is known that the life of battery systems is reduced if they are frequently overcharged (alkaline battery systems and lead acid batteries) or if them at high charge levels operated or stored (including lithium systems).

Based on this behavior, which is known per se a rechargeable battery, it is an object of the present Invention, a charging method for to provide a rechargeable battery which is compared to conventional charging processes is more energy efficient and saves life.

This task is accomplished through a charging process for a rechargeable Battery with the features specified in claim 1 solved. Other configurations and advantageous developments are the subject of the dependent claims.

The charging process for a rechargeable Battery according to the present Invention is characterized in that the charging process of the battery dependent on from the time of a next one Use of the battery and / or the next time the battery is used required state of charge of the battery is controlled. In other words The charging process is based on whether at the time of the next use the maximum possible battery capacity to disposal must stand or whether possibly a partial charge of the battery is sufficient, and / or afterwards, when the next Battery usage is taking place.

The invention is based on knowledge from that in most uses of a battery not the total capacity of the battery is necessary and that in many cases the time of the next use the battery is known. It is therefore by means of the charging method according to the invention possible, the energy losses due to low charging efficiency and high Lower self-discharge rates by only using the battery up to theirs the next time you use it indeed required State of charge, which is common still in a range of high charging efficiency and lower Self-discharge rates lie to charge. It can also cause energy loss The self-discharge effects are minimized by the charging process at the time of the next Use of the battery is coordinated, i.e. the charging process of the battery to the desired one State of charge if possible only immediately before the next time the battery is used he follows. The effects of the charging method according to the invention are in particular advantageous for alkaline battery systems where high efficiency or low power losses are desired, such as this for rechargeable batteries of electric vehicles and hybrid vehicles the case is.

They also have some battery systems immediately after a charging process, the property of a higher voltage level and / or a lower internal resistance so that the charged battery in the event of the charging process being carried out immediately before the time of the next use Beginning of the subsequent Period of use a higher Willingness to perform or lower losses due to the lower Internal resistance shows.

The charging process of the battery is preferably additionally controlled as a function of the battery temperature, since the characteristics of the charging efficiency and the rate of self-discharge are again controlled rechargeable batteries generally also depend heavily on the battery temperature.

It can also be advantageous if the charging efficiency immediately before the next use of the battery clear, i.e. for example below 90% or even below 80%, has dropped. The lowering of the charging efficiency leads to the charging process to an increase in battery temperature. Because in general the internal resistance of the battery decreases with increasing temperature, does this as described above in the subsequent period of use increase the willingness to perform and a reduction in internal resistance losses. For batteries for Electric and hybrid vehicles can do this particularly in the cold Be of advantage to the battery at the beginning of the season Have brought the operating temperature to the operating temperature.

In a preferred embodiment the invention is the charging process of the battery in a first charging period, in which the battery is charged up to a first state of charge, and a second charge period in which the battery is up to a second charge state larger than the first state of charge is charged, divided the second Charge period immediately before the next use of the battery lies. The first charge status at the end of the first charge period is preferably between about 50% of the nominal capacity of the battery and a state of charge, where the charging efficiency has not yet dropped noticeably and the Self-discharge rate has not yet increased significantly, such as at about 75% of the nominal capacity the battery, and between the first charging period and the second Charging period, a charging break is preferably provided, in which no battery charging takes place, the length of the charging pause between the first and the second charging period depending on the time the next Use of the battery is determined.

In this way it is possible Battery in a first charging period up to a first state of charge charge, on the one hand the charging efficiency is still high and the self-discharge rate is still low and on the other hand ready one certain battery charge for unforeseen uses are available at an earlier date. After a charging break, in which due to the not too high State of charge a relatively low self-discharge of the battery takes place, the battery is then immediately before the next use the battery to a second state of charge, which the for the next Use required charge level corresponds. Because the second charging period immediately before the next Use occurs, energy loss due to self-discharge despite the higher Battery charge status minimized.

In a further embodiment of the extension the battery can cool down before the first charge period dependent on cooled by the battery temperature the charging efficiency during subsequent charging periods to increase.

It is also possible to one later than expected next Use the battery to self-discharge the battery through regular short Compensate charging pulses.

The time of the next use the battery or the next one Use of the battery can charge the battery either entered manually by a user or - preferably by means of a adaptive process - off previous usage profiles of the battery can be determined independently. In the latter Case, the user or the battery control unit at a desired Deviation from the previous usage profiles the time of next Use the battery or the next time you use the battery Set the required state of charge of the battery if necessary.

The charging process of the present The invention can advantageously be used with a rechargeable battery an electric vehicle or a hybrid vehicle.

The above and other advantages and Features of the present invention will become apparent from the following description of preferred embodiments the invention with reference to the accompanying drawings easier to understand. In it show:

1a ) a schematic representation of the timing of the charging process for a rechargeable battery according to a first embodiment of the present invention;

1b ) a schematic representation of the timing of the charging process for a rechargeable battery according to a second embodiment of the present invention;

2 a graphical representation of the charging efficiency versus the state of charge as a function of the battery for an alkaline battery system; and

3 a graphical representation of the self-discharge rate over the state of charge as a function of the battery for an alkaline battery system.

In order to charge a rechargeable battery using the charging method of the present invention in the most energy-efficient and life-saving manner, the time t _{Nutz of} the next use of the battery and the state of charge SOC _Nutz of the battery required for the next use of the battery are first determined. This can be done, for example, by the user directly entering this data or, independently, using an adaptive method from the previous usage profiles of the battery. Since the usage profiles of rechargeable batteries change frequently (at least least approximately) repeat, the time can be _useful t the next use of the battery and the space required for the next use of the battery state of charge SOC determined or estimated _useful battery from previous usage profiles.

Since, in exceptional cases, the battery must be fully charged contrary to the previous usage profiles, the user or the battery control unit can set the data t _Nutz and SOC _Nutz independently of the previous usage profiles and the values for t _Nutz and SOC _Nutz determined from them , Such exceptional cases exist, for example, if the user wishes the battery to be fully charged because, for example, he can predict that the battery will have to be provided with a higher energy than usual in the next period of use. In the case of alkaline battery systems and lead acid batteries, the battery control unit can also demand an equalizing charge for the battery in the form of a moderate overcharge of the battery, for example because the individual charge states of the cells of the battery have drifted apart. By moderately overcharging the entire battery system, the individual charge levels of the cells align again. Furthermore, the battery control unit may also require a full charge, for example, in order to recalibrate the battery parameters stored in the battery control unit in order to be able to adapt the parameters to the aging state of the battery, for example.

If the two parameters t _Nutz and SOC _{Nutz are} known or predefined, the charging process of the battery takes place according to a first exemplary embodiment in accordance with that in FIG 1a ) schematically shown timing.

In a first charging period T1, the battery is charged to a first state of charge. This first state of charge is preferably more than about 50% and less than about 75% of the nominal capacity of the battery. The lower limit of about 50% (generally about 40 to 60%) means that the battery provides a certain capacity, even in the event of an unforeseen earlier use of the battery, which ensures that the battery is used. The upper limit of approx. 75% (generally approx. 65 to 80%) was chosen because up to a state of charge SOC of approx. 75% in the usual temperature ranges of the battery there is only an insignificantly reduced charging efficiency η and an insignificant self-discharge rate K (see 2 and 3 ). Depending on the field of application of the battery and the actual battery temperatures, the two limit values or limit value ranges mentioned can of course be adjusted.

During the first charging period T1, the battery is thus charged with a very high charging efficiency η, that is to say very energy-efficiently. The first charging period T1 follows, as in 1a ) to recognize a charging pause T3 in which the battery is not being charged. The length of the charging pause T3 depends on the time t _Nutz the next time the battery is used; the charging break T3 may even have to be omitted if the time until the time t _{use of} the next use is too short. During this charging pause T3, there is only a very slight self-discharge of the battery, since the self-discharge rate K is still very low with a state of charge SOC of at most 75%, as is evident from 3 seen.

In good time before the time t _{use of} the next use of the battery, a second charging period T2 takes place after the charging pause T3, in which the battery is charged to a second state of charge which is greater than the first state of charge. In general, that except in the above-described exceptional cases and the like, the second state of charge corresponds to the required at the next use of the battery state of charge SOC _useful. The charging process of the battery is resumed as possible after the charging break so that the end of the second charging period T2 lies immediately before the time t _{use of} the next use of the battery. Since the battery is charged to the SOC _Usable state of charge immediately before the battery is used, the self-discharge of the battery is minimized, which would otherwise take place in the state of charge above approximately 80% during periods of non-use of the battery (see 3 ).

In this way, a high charging efficiency is guaranteed over the entire duration of the charging process, ie in particular during the first and the second charging period T1, T2, and a low energy loss is ensured during the idle time, ie in particular during the charging break T3. Energy saving and protection of the battery is also achieved in that the battery is only charged up to a state of charge SOC _Nutz , ie is not unnecessarily charged or even overcharged, which is required for the next use. This energy saving is all the more significant since the charging efficiency decreases significantly in the case of higher charging states up to the full charge of the battery, in particular in the case of alkaline battery systems.

At this point, it is expressly pointed out that the charging method of the invention can in principle be used independently of the charging principle used (for example constant current charging, constant voltage charging, pulse charging, Reflex ^® charging principle and the like) and unfolds its advantages. Furthermore, the charging method of the invention is in principle also independent of the strength of the charging current or the charging power. Of course, however, it is advantageous to select the charging current or the charging power appropriately from the point of view of energy and / or life-saving. In addition, in the normally slow charging processes, batteries generally also have a higher charging efficiency at higher charging currents, so that especially in the case of electrical or hybrid vehicles should be charged with the maximum possible charging current.

If there is more time until the time t _use the next time the battery is used, the battery charging process can be 1b ) shown second embodiment of the loading method of the extension.

At the in 1b ) shown charging process, the battery is cooled before the start of the first charging period T1 during a cooling period T4. Since the charging efficiency η drops at higher battery temperatures and the self-discharge rate K of the battery also increases (see 2 and 3 ), such a cooling period T4 can be very useful, since the subsequent first charging period T1 then takes place with a higher charging efficiency η.

Following the cooling period T4, the charging process of the battery is analogous to the first exemplary embodiment of 1a ) with a first charging period T1, possibly a charging break T3, and a second charging period T2. The explanations given above in connection with the first exemplary embodiment relating to the periods T1 to T3 of the charging process also apply analogously to the exemplary embodiment of FIG 1b ), which is why there is no further explanation.

If, contrary to expectations, the battery is not used at the time t _{use of} the expected next use, then the self-discharge of the battery which is then present can optionally be compensated for in the two exemplary embodiments described above, so that the desired state of charge SOC is then also available at the later actual time of use. This compensation can take place, for example, by means of further short charging pulses at regular intervals, as is the case in the 1a ) and 1b ) is indicated on the far right on the timeline.

Claims (13)

Charging process for a rechargeable battery, in which the charging process of the battery is controlled as a function of the time (t _Nutz ) of a next use of the battery and / or the state of charge (SOC _Nutz ) of the battery required the next time the battery is used. Loading method according to claim 1, characterized in that the charging process of the battery is also dependent is controlled by the battery temperature. Charging method according to claim 1 or 2, characterized in that the charging efficiency is evident immediately before the next use of the battery has dropped. Loading method according to one of claims 1 to 3, characterized in that the charging process of the battery is a first charging period (T1) in which the battery is charged up to a first State of charge is loaded, and a second charging period (T2) in which the Battery up to a second state of charge greater than the first state of charge (T2> T1) is loaded, the second charging period immediately before the next use of the battery. Loading method according to claim 4, characterized in that the first state of charge is between about 50% of the battery's nominal capacity and a state of charge in which the charging efficiency is not yet noticeable decreased and the self-discharge rate has not yet risen appreciably is, is. Charging method according to claim 4 or 5, characterized in that between the first charging period (T1) and the second charging period (T2) a charging pause (T3) is provided, in which the battery is not charged, the length of the charging pause between the first and the second charging period depending on the time (t _Nutz ) of the next use of the battery is determined. Loading method according to one of claims 4 to 6, characterized in that before the first charging period (T1) the battery while a cooling period (T4) depending cooled by the battery temperature becomes. Loading method according to one of claims 1 to 7, characterized in that a later than expected next Use the battery to self-discharge the battery through regular short Charge pulses is balanced. Charging method according to one of claims 1 to 8, characterized in that the time (t _Nutz ) of the next use of the battery or the state of charge (SOC _Nutz ) of the battery required the next time the battery is used is entered by a user. Charging method according to one of claims 1 to 8, characterized in that the time (t _Nutz ) of the next use of the battery or the state of charge (SOC _Nutz ) of the battery required the next time the battery is used is determined from previous usage profiles of the battery. Charging method according to claim 10, characterized in that the time (t _Nutz ) of the next use of the battery or the state of charge (SOC _Nutz ) of the battery required for the next use of the battery is determined independently by means of an adaptive method from previous usage profiles of the battery. Loading method according to claim 10 or 11, characterized in that in the event of a deviation the time (t _Nutz ) of the next use of the battery or the state of charge (SOC _Nutz ) of the battery required for the next use of the battery is set by the user or a battery control unit if necessary from the previous usage profiles. Loading method according to one of the preceding claims, characterized characterized in that the rechargeable battery is a rechargeable battery an electric vehicle or a hybrid vehicle.