DE3815001A1 - DEVICE FOR CHARGING ACCUMULATORS - Google Patents

Abstract

A device 21 permanently associated with a battery pack stores the time-related patterns of the actual charging and discharging currents, battery voltage, temperature and pressure and also stores desired profiles of these parameters, comparisons between the actual and desired profiles providing output signals ES which control a charger. The signals ES also includes data indicative of battery type. The device 21 may comprise a microprocessor 9, memory 10, analog/digital converter 11, comparator 12, temperature monitor 13, battery type recognition device 14, current measuring circuit 16, input/output interface 17 and a display 60. The charger may include decoders (30), (31), (Fig. 4), responding to the outputs ES to provide signals (S6), (Q6), (66), (EL) for selecting between fast, semi-fast, slow and trickle charging and signals (T1) to (T8) indicative of one of eight possible battery types. A further circuit (32) receives these decoded signals to insert an appropriate one of thirty two resistors (R1) to (R32) in series with the battery, and charging current device. Alternatively, charging may be controlled by thyristors, (Figs 8, 9), or by tap-charging on a transformer, (Fig 10). <IMAGE>

Description

The invention relates to a device for charging rechargeable batteries lators, in particular of nickel-cadmium accumulators (NC), the one device for identifying the battery type and possibly have to sense its temperature, according to the characteristics of the preamble of claim 1.

Accumulators, in particular high-current-resistant nickel-Kadmiun batteries (NC batteries) are very expensive electricity suppliers for off-grid devices to be operated that only then operate to a certain extent Lich can be used if the life of the ver batteries used is relatively long.

The lifespan of each battery, but especially one Accumulator of the type mentioned at the beginning, but depends very much essentially from its usage profile, from its first inheritance drive up to the present time. This Be usage profile represents the timeline of its operations parameters regarding charging current, discharging current, cell voltage, temperature and pressure.

While the operational discharge of a battery in a battery-operated device is largely determined by the use of the device, there are certain options for recharging the battery, ranging from fast charging, quasi-fast charging and slow charging to trickle charging. Chargers that can be switched to these different charging modes are already used today. The criteria that are used in detail for switching between the operating modes are based on general physical considerations, which essentially derive from the diagram in FIG. 5, which shows the characteristic states of a single specific NC cell. The curves shown are both type-specific and cell-specific. The permissible range of the cell-individual curve profiles can thus be represented for each cell type by a family of curves, which is given by the upper and lower, still tolerable values.

Special problems for the life of a battery arise if it is operated with excessive discharge and / or charging current, overloaded or below a certain level casual minimum cell voltage is discharged. Problems occur also in the fast charging, of which the user himself operated to have his device ready for operation again quickly or the number of batteries used for cost reasons to keep it as small as possible in order to keep one as uninterrupted as possible Maintain operations. On the one hand, you want one Schnelladen also be sure that after a full The cell (s) are really full. On the other hand the battery can also tolerate a certain overcharge. Becomes However, if it is overloaded, the pressure in it increases Gas development very quickly so quickly that the built-in Safety valve responds and the cell may be off running. Opening the safety valve turns a Avoid damage that leads to cell (s) destruction; it however, a reduction in capacity remains.

An often practiced and reliable way of charging a battery is to discharge it completely beforehand and then charge it with a certain current for a certain time. This avoids that a half-full battery is overcharged, with the consequences mentioned above. Fig. 5 shows that the voltage increases very quickly and the pressure and temperature rise only slowly with increasing charging. As a result, a growing proportion of the energy supplied is converted into gas (oxygen) in the cell, which cannot be chemically bound in the electrodes in the time available. The pressure rises accordingly and causes part of the released oxygen to bind to the negative electrode under heat development. With increasing temperature, the voltage drops again. NC cells therefore have a negative temperature coefficient of around -4 mV / ° C. This explains the course of the voltage characteristic of the cell with the initially increasing voltage, which increases slightly after full charge (100%) is reached, but then decreases again with increasing overcharge. Most of the energy supplied is also converted into heat, as FIG. 5 also shows. The parameters shown are a measure of the state of charge of a cell and reliable information for a charger which carries out, monitors and terminates the charging process.

Chargers for NC batteries with slow-fast and ouasi-fast charge are well known. For example, in the DE-OS 26 51 067 describes a quick charging device in which a battery to be charged initially with an increased charge current up to a predetermined percentage of the to be achieved Final charge voltage is charged, then at this first Schnelladeabschnitt another loading section with redu decorated charging current over a predetermined time. Here will be added to safely avoid harmful overloading Lich suggested the second loading section prematurely if necessary switch off when a predetermined terminal voltage or a predetermined temperature of the battery reached or above is taken.

This charging device works just like other known ones Fast charging facilities on the assumption that a re charging after a specified time or at a full charge certain terminal voltage was reached and that after the Ab switch each individual accumulator to approximately full Nominal capacity is charged. But this is often not the case Case, because of various influences over time (Operating time, overloads, short circuits, etc.) in one Such accumulable energy decreases more and more. This decrease in loading capacity will generally only become apparent  then determined when that to be operated with the accumulator Device suddenly during its operational readiness fails, which is particularly the case with all emergency units, however also walkie talkies in disaster operations not tolerable is. This ignorance of the actual history of a Accumulator before recharging leads to always un more favorable conditions for the battery, so that it in a way is being charged, the faster and faster to further capacity loss until it becomes unusable.

The present invention therefore has the task of to provide a solution with the batteries, especially those that are not permanently assigned to a device bar, which are related to a long battery life Current resistance and high capacitance values.

This object of the invention is achieved by the main claim specified characteristics.

Further advantageous refinements and developments of The invention relates to the subclaims to take.

The way shown by the invention for an individual battery Charging in fully automatic chargers leads to the pre part of a long battery life while maintaining one capacity and current resistance as large as possible.

In the following the invention with reference to drawings described embodiment described. Show it:

Fig. 1 is a schematic representation of an NC battery with built-in type identification and integrated temperature sensor,

Fig. 2 is a block diagram of a device for generating and storing a usage and / or operation parameter profile and for generating control signals for a battery charger,

Fig. 3 is a block diagram of a battery charger,

Fig. 4 is a block diagram of a charging circuit,

Fig. 5 is a graph of operating parameters of an NC-cell

Fig. 6 is a schematic diagram of a current measuring device,

Fig. 7 is a schematic diagram of a charger with a series parallel converter for the supply of a control signals and

Fig. 8 to 10 schematic diagrams of chargers with thyristor circuits.

Because of the normally usual separation of battery, consumer and charger, which means that when using multiple batteries, consumers and chargers a clear assignment is no longer possible, a device is provided in the battery, which shows the chronological course of charging and discharging currents, voltage, temperature and pressure registered. Such a device can be accommodated in the battery pack, that is, if necessary, interconnecting several NC cells to form a package, if the technology of microelectronics is used. Previous battery packs, as shown in FIG. 1, contain, in addition to the NC cells ( 2 ), identifying elements ( 3 ), which are resistors, diodes or the like, for identifying the battery type and possibly temperature sensors (4), which are connected via the external connections ( 5 to 8 ) can be connected to a charger.

A device that can both generate and store the time profile of the above-mentioned parameters is shown in principle in FIG. 2. It can consist of a rigid or flexible circuit card ( 21 ) which holds one to several semiconductor chips ( 9 to 17 ), the necessary wiring and the connections to the outside world.

In the course of a desired low power loss in the range of a few picowatts, the well-known CMOS technology, which is available in several variants, will be used for the construction of the circuits in the microchips. The main element of the device ( 21 ) is a microprocessor (MP; 9 ), which itself has a read-only memory (ROM) in which, for example, its control program is located. The additional electrically erasable and programmable read memory (EEPROM; 10 ) is used to record the measurement data, which are processed and saved for the parameter profiles. In addition, it contains tables that represent battery type-specific groups of curves of the parameters and thus contain the permissible range of these parameters.

Furthermore, a clock generator (TG; 16 ) is provided, which synchronizes the processes in the device ( 21 ) and serves as a time base for the registration of the time course of the parameters. Communication with the outside world takes place via an interface (SCHN; 17 ), via which analog input signals, the voltages, voltage-dependent resistance values, temperature and pressure-dependent resistance values and type identification signals in the form of resistance values or diode voltages are fed and via the digital output signals (ES) for setting a desired charging current to a charging circuit ( 29 ) are transmitted.

The aforementioned analog input signals of the battery voltage (UAK), the type identification (ID), and the temperature sensor (TF) must first be converted into a digital form of representation in an analog / digital converter (A / D; 11 ) so that their digital processing in the microprocessor ( 8 ) and the other components, a comparator (VGL; 12 ) a temperature monitor (TÜ; 13 ), a type recognition device (TE 14 ) and a current measuring circuit (STM; 15 ) is possible.

If the number of lines, for example those which are connected to the connection points ( 22 to 26 ) and which transmit the setting signals (ES) to the charger ( 27 ) in FIG. 3, are to be limited as far as possible to one line, then must be done in the device ( 21 ) a series / parallel converter can be connected to the corresponding outputs of the interfaces ( 17 ), which in the simplest case can be a 5-digit shift register. In operation, its five stages are charged in parallel and then serially transmitted to the charging circuit (LS; 29 ) in the charger ( 27 ) via an output. This is then, in deviation from the illustration in Fig. 3, a series / parallel converter upstream, which can also consist of a 5-digit shift register whose five stages can be loaded serially and read out in parallel. The parallel outputs are connected to the inputs of the charging circuit ( 29 ). Both in FIG. 2 and in FIG. 3, these converters are not shown (but see FIG. 7).

To derive the pressure parameters, a pressure sensor must be provided in the battery pack ( 1 ), which, depending on its underlying physical principle, generates a voltage or a resistance value corresponding to the respective pressure. Such an ana log value is then also supplied via the interface ( 17 ) and fed via the analog / digital converter ( 11 ) to digital further processing.

To detect the currents (charging and discharging currents), a Hall generator (HG; 37 ) is used before, which measures the magnetic field of an extremely low-voltage coil ( 36 ) which is switched on in the main current path. The result is a Hall voltage that depends on a material constant, a cross current and the strength of the magnetic field of the coil in the main current path. Since the strength of the magnetic field in turn depends on the current in the main current path, the charge or discharge current flowing in the main current path and thus through the coil can be used to measure the current. The current measuring device ( 15 ) can, in conjunction with the measuring circuit ( 35 ), which is connected via the interface, perform the calculation of the charging or discharging current. It should be mentioned at this point that the functions of the circuits on the chips ( 11 to 15 ) can also be relocated to a microprocessor ( 9 ) of appropriate intelligence.

A display device (ANZ; 60 ) can also be of great use, which allows the current state of charge of the associated battery or other battery data of interest that are stored or are currently being sensed to be displayed.

We recommend single or multi-digit numeric or alphanumeric liquid crystal displays, which are known only have a low power loss.

In principle, it does not matter whether the display device on the circuit card itself or separately from it is arranged in the battery pack. A separate arrangement is only spoken by the additional connection ( 61 , 62 ), which represents a possible later source of interference.

The temporal course of the currents (charge and discharge currents) can thus also be stored in the memory ( 10 ). A data bus (DB; 20 ), a clock bus (TB; 19 ) and a control signal bus (STB; 18 ) are available to carry out the data processing and control functions, which connect the individual system components with each other.

The charger ( 27 ) shown in Fig. 3 no longer requires a high level of self-intelligence for a gentle battery charge, since this is mainly in the device ( 21 ) installed in each battery pack. It therefore only consists of two components, namely the power supply (SV; 28 ), which generates a DC voltage of the desired level from the mains voltage or the voltage of a suitable battery or other suitable accumulator.

This DC voltage is applied to the battery pack via a charging circuit ( 29 ). In a manner not shown in FIGS . 3 and 4, the type-specific setting signals which are applied to the charging circuit ( 29 ) via the contacts ( 24 to 26 ) can also be used in the power supply circuit ( 28 ) to generate differently high DC voltages be, which are supplied via ( 33 and 34 ) of the charging circuit ( 29 ). Part of the output signals ( T 1 to T 8 ) of the decoder ( 31 ) can be transmitted to the power supply circuit ( 28 ) in order to generate these different DC voltages, which are required for charging battery packs of different nominal voltages.

Fig. 4 shows one of several possible variants for the generation of the charging currents for four charging modes and eight different types of battery packs. The setting signals (ES), which are applied to the charging circuit ( 29 ) via the connections ( 22 to 26 ), reach a first binary decoder (DEC1; 30 ) and a second binary decoder (DEC2; 31 ). While the first decoder ( 30 ) from the first two control signals, which are brought in via the first two connections ( 22 and 23 ), the charging mode signals for quick charge (SL), for quasi-quick charge (QL), for slow charge (LL) and for generate the maintenance charge (EL), the following setting signals at the connections ( 24 to 26 ) are decoded into the type signals ( T 1 to T 8 ) by the second decoder ( 31 ).

A downstream third decoder (DEC3; 32 ) generates 32 control signals, each of which is representative of a charging mode of a battery pack type. Fig. 4 shows a decoder ( 32 ) which decodes the 12 input signals (SL to EL and T 1 to T 8 ) according to the principle 1 of 32. The resulting signal from this decoder ( 32 ), for example (SL / T 1 or EL / T 1 or EL / T 8 ) can be considered as a control signal of a controllable switch ( S 1 to S 32 ), which has a current limiting resistor ( R 1 to R 32 ) loops into the main charging current line. Such a main power line runs, for example, over the + line at the connection point ( 33 ), a closed switch (Si), a current limiting resistor (Ri), the connection point ( 5 ), the positive pole of a battery pack ( 2 ) ( Fig. 1) and the connection point ( 6 ) according to device dimensions.

With a favorable design, two or more current limiting resistors can be connected in parallel, so that the amount of components can be reduced in this way. The decoder ( 32 ) would then have to have a different internal structure, which allows it to use other decoding principles, which takes into account the variety of charging currents on the one hand and the reduced component expenditure for the current limiting resistors (Ri) and selection switches (Si) on the other.

Another embodiment of a charger, which can be controlled by a device ( 21 ) individually assigned to a battery pack, is shown in FIG. 7. The charger ( 43 ) shown there in turn consists of a power supply ( 45 ) and a charging circuit ( 46 ), the latter the setting signals are supplied serially via the connection ( 22 ). The setting signals go to the charging circuit ( 46 ) via a shift register (SR 44 ) connected as a series / parallel converter. The bitwise transmitted setting signals, which arrive serially at the input ( E ) of the shift register ( 44 ), are shifted into the five stages with the aid of five shift pulses which are applied to the clock input of the shift register. At the outputs of the five stages of the shift register, the five control signals can now be tapped in parallel, until new setting signals are transmitted from the device ( 21 ) to the charger ( 43 ), thereby setting a different charging current and / or a different charging voltage .

The schematic diagram in Fig. 7 also allows the assumption that the power supply circuit ( 45 ) makes use of controllable rectifiers with thyratronic characteristics. The charging circuit ( 46 ) then contains the controls, also called ignition elements, which set the desired current flow angle. The setting signals (ES) are then used, either in the manner already explained in connection with FIG. 4 with the aid of the controllable switches ( S 1 to S 32 ) with ignition elements (ZGLi ;, 53 , 54 , 55 , ...) with defined Ignition times (determined by the RC-elements contained in them) to be applied to the control electrode (SE) of a thyratron ( 52 ) for setting the desired current flow angle, or, as shown in FIG. 8, in a charger ( 47 ) of another type, for example in a bridge circuit (BS) in a power supply ( 48 ) to control the thyristors ( 52 ) via a control line ( 51 ) by means of an ignition element ( 50 ), in which the setting signals brought about by the connection point ( 22 ) from the device ( 21 ) (ES), which were already generated as trigger pulses with regard to the charging mode and the battery pack type, which, as can be seen in FIG. 8, leads to a particularly economical embodiment of the charger ( 47 ).

Claims (16)

1.Device for charging accumulators (accumulators) which have devices for identifying the type of battery and, if appropriate, for sensing its temperature, with a power supply device and with a charging circuit, which has a switching device for the charging mode as fast, quasi-fast, Slow or trickle charge for one or more battery types, characterized in that for setting the charging mode and thus the charging currents of the charging circuit ( 29 ), the same setting signals (ES) are supplied, which are obtained by comparing the respective battery ( 1 ) dedicated device ( 21 ) formed and stored individual charging current, discharge current, voltage, temperature and / or pressure-time profile can be derived with an also stored target profile. 2. Device for charging batteries according to claim 1, characterized in that the one battery or a battery pack ( 1 ) permanently assigned device ( 21 ) has a data processing arrangement ( Fig. 2) which has at least one microprocessor ( 9 ), a memory ( 10 ), an analog / digital converter ( 11 ), a comparator ( 12 ), a clock ( 16 ), a temperature monitor ( 13 ), a battery type detection circuit ( 14 ), a current measuring device ( 15 , 35 ) and contains an interface circuit ( 17 ) which are connected to one another by means of a data bus ( 20 ), a control signal bus ( 18 ) and a clock bus ( 19 ). 3. Device according to claim 1 and / or 2, characterized in that the components ( 9 to 16 ) of the battery permanently assigned device ( 21 ) are arranged on a circuit card which has the necessary connecting lines (for example 18 to 20 ). 4. Device according to one or more of the preceding claims, characterized in that the memory ( 10 ) of the data processing arrangement is an electrically erasable and programmable readable memory of the EEPROM type, which does not lose its content in the event of a power failure. 5. Device according to one or more of the preceding claims, characterized in that the memory ( 10 ) is a dynamic or static read / write memory (RAM) to which an EEPROM (memory) is assigned, when the battery voltage under one Predeterminable minimum value drops, which takes over data that is urgently required for a continuation of operation. 6. Device according to one or more of the preceding claims, characterized in that an interruption switch is provided in the main current path ( 5 , 5 a , 6 ) which opens the main current path at He a predetermined minimum voltage on the battery when discharging to deep discharge and possibly Avoid polarity reversal of the battery cells. 7. Device according to one or more of the preceding claims, characterized in that the functions of the analog / digital converter ( 11 ), the comparator ( 12 ), the temperature monitor ( 13 ) and the battery perimeter ( 14 ) integrated in the microprocessor ( 9 ) are. 8. Setup according to one or more of the preceding Claims, characterized in that at least the in Claim 1 mentioned target profiles saved in tabular form are. 9. Device according to one or more of the preceding claims, characterized in that the setting signals (ES) calculated from the comparison of the actual values with the target values of the said profiles by the microprocessor ( 9 ), which are serial or parallel to the charging circuit ( 29 ) of a charger ( 27 ) are transmitted to at least one decoder ( 30 , 31 , 32 ) which generates the charging mode and battery-specific control signals (SL / T 1 to EL / T 8 ; Fig. 4), which in turn each have a controllable switch ( S 1 to S 32 ) set, each of which loops a current limiting resistor ( R 1 to R 32 ) corresponding to a desired charging operation and battery type into the main current path. 10. The device according to claim 9, characterized in that the / the decoder ( 30 to 32 ) also generate two or more parallel control signals (for example SL / T 1 , EL / T 1 ), whereby two or more controllable switches (for Example S 1 , S 4 ) are set and two or more current limiting resistors (for example R 1 , R 4 ) are looped in parallel into the main current path. 11. The device according to claim 9 or 10, characterized in that a part of the control signals derived from the setting signals (ES) by decoding (for example T 8 ) is transmitted to the power supply device ( 28 ) ( Fig. 10), where at least one controllable switch (S) sets a different output voltage (UV1, UV2). 12. The device according to one or more of claims 1 to 9, characterized in that the setting signals (ES) after their decoding to control signals (SL / T 1 to EL / TB) by means of the same controllable switch, the ignition elements ( 53 to 55 ) to set individual current flow angle, which correspond to a desired charging mode for a desired battery type, to the control electrode (SE) of a controllable rectifier ( 52 ) with thyristor characteristics. 13. Device according to one or more of the preceding claims, characterized in that a display device ( 60 ) is provided which is connected to the device ( 21 ) and stored and / or just derived state values of the battery parameters (charge, voltage or the like. ) displays. 14. The device according to claim 13, characterized in that a single or multi-digit numerical or alphanumeric liquid crystal display is provided as the display device ( 60 ). 15. The device according to claim 13 or 14, characterized in that the display device ( 60 ) is arranged on the circuit card. 16. The device according to claim 13 or 14, characterized in that the display device ( 60 ) is arranged separately from the circuit card in the battery pack.