DE2557010A1 - PROCESS FOR FAST AND CONTINUOUS CHARGING OF GAS-TIGHT NICKEL / CADMIUM ACCUMULATORS - Google Patents

Abstract

The constant current is applied during the first part of the charging process and the first phase is ended when a specified voltage is reached. This voltage is such that 70 to 90% of the nominal capacity is charged. After the first phase a pause of a specified length is applied. Then the battery is charged by pulses of the same intensity until the specified voltage is again reached. The charging pulse keying ratio is such, that 10 to 30% of nominal capacity is charged in 24 hours.

Description

Procedure for fast and continuous charging of

gastight nickel / gadmium accumulators The invention relates to a method for fast and long-term charging of gas-tight nickel / cadmium batteries, in which the accumulator in the first charging phase with a constant current of 2 to 4 110 is charged up to a cut-off voltage and the cut-off voltage is dimensioned in this way is that in this charging phase 70 to 90% of the nominal capacity is charged.

Fast and accelerated charging methods for charging gas-tight alkaline batteries are known. For example, in a first Strong charge phase with constant current between 8 and 20 110 with quick charge or between 2 and 4 I10 loaded with accelerated loading. Then when a given battery voltage value with constant current pulses, whereby the constantatromic pulses always start when a specified lower voltage value the battery voltage is reached and terminated when the switch-off voltage on the battery. The disadvantage of this process is the temperature dependence of the accumulator and the dependency on the aging of the accumulator.

Especially with off-grid household appliances that are rechargeable Batteries are operated is usually a so-called charging method Continuous charging used. The accumulator is constantly supplied with a current of at least 1/5 I10, normally charged with a current of 1/3 I1D. For a cell with a capacity of 500 mAh, as used in cordless household appliances, among other things a continuous charging current of 1/3 110 is 15.7 mA, i.e. with a Continuous charging 40 (1 mAh) are charged or recharging over 24 hours.

This corresponds to 80% of the nominal capacity / day. Because taking into account a charge factor of 1.4 in a discharged battery again 140% of the nominal capacity must be charged in order to reach the Uolladestatus, is with this trickle charge full capacity is reached soon and especially if the device is used for long Time remains at the setting tool without being used, there is a constant overload, which can have a detrimental effect on the operation of the accumulator.

With repeated stress, on the other hand, if there is not enough time is available for long-term charging, the charge status is insufficient in the short time can be achieved.

The invention is therefore based on the object of a charging method to develop which one recharges the battery within a short period of time and in which in recharging or continuous charging operation too high a capacity throughput is avoided by the accumulator.

This task is solved in that one of the first loading phase Charging pause of a predetermined period of time follows and that then the accumulator is pulsed with the same amperage as in the quick charge phase, in each case until it is reached the switch-off voltage is recharged, the ratio between charging pause and Impulse duration is measured so that in the reloading phase within 24 hours only 10 to 30% of the nominal capacity can be recharged.

It is thus avoided that when the battery is fully charged during continuous charging There is always a high capacity throughput, as is the case with continuous charging, for example with 1/3 I10, with a capacity throughput of approx.

80% of the nominal capacity is the case every day.

The curve of the charging voltage is detailed below with reference to FIG explained. In this case, the accumulator is preferably supplied with constant current in time To charged with a current of the order of magnitude of 3 I10, up to the cut-off voltage UA. The battery voltage increases according to curve 1. The current is with the characteristic 3 shown. The cut-off voltage is just below this in a manner known per se the maximum achieved with continued charging on the gas-tight accumulator Tension, for example, uus usual at about 1.46 volts.

There is then a charging pause of a predetermined period of time T1 with a Current I = 0. During this pause, the battery voltage falls according to the curve 2. After the specified period of time, the accumulator is again charged with the boost charge charged impulsively, i.e. again with 3 I1u for example. The battery voltage increases according to the characteristic curve 1 'and when the switch-off voltage is reached, it is switched off again.

The charging pause for the specified time period T1 then takes place again, in which the battery voltage drops according to the characteristic curve 2 'and then again a charging current pulse T3 (current 3), which, since the cut-off voltage according to the characteristic 1 "is reached faster, has a shorter duration than the charging pulse T2.

The length of the charging current pulse in the continuous charging time is at the beginning of trickle charging and gradually decreases and becomes almost constant. at a cell with 50D mAh and a pulse charging current of 2.5 1113 has been found in a an appropriate pause time of approx. 3 minutes a length of the current pulse of approx. 8 Seconds. This results in a recharge of Z8 mAh in 24 hours, i.e. about 26% of the nominal capacity / day. The ratio of charging pause to pulse duration is Basically dimensioned in such a way that 10 to 3D% of the nominal capacity in the pulse charging phase can be recharged within 24 hours.

The relationship between charging pause and pulse duration should be selected so that that the charging current pulse can be kept as short as possible. It will be the choice the current pulse length, however, is influenced by the properties of the cell itself, so that, for example, in the case of the said cell of 500 mAh, a charging pulse duration of 8 seconds has proven to be useful.

This ratio of pause to charging time in the pulse charging phase should between 50: 1 and 10: 1, preferably between 20: 1 and 30: 1. Included is on the one hand a sufficient increase in voltage during of the current pulse Given1 so that a proper shutdown with simple technical means can be made, on the other hand, the charging break with simple electrotechnical Funds can still be safely set.

A circuit for carrying out the charging method according to the invention is shown in FIG. The circuit arrangement, which is via transformer 1 and Elelchrichter 2 is on the network, consists essentially of a Kunstantstromque11e from resistor R1, diodes D4 and D3 and transistor T1 and a timer the resistor Rz, capacitor C1 and Zener diode Z1, through which the control grid of a thyristor Th1 can be controlled, which is connected to the base of the transistor Trüber resistance R4 is connected. When the device is started up, a current flows through resistor R2 in capacitor C1. The voltage value on the capacitor increases up to the breakdown voltage the Zener diode Z1, whereupon the thyristor Th1 switches through and via resistor R4 transistor T1 is turned on. At the same time, the capacitor begins to discharge C1 via resistor R3 and diode D1.

After reaching the Abechalta voltage on the accumulator 3 of for example 1.46 V / cell is generated via the adjustable voltage divider consisting of resistor R5 and potentiometer P1 the thyristor Th2 ignited. The grid-cathode path of thyristor Th1 becomes shorted out and the thyristor Th1 is pulsing at the end of a period DC voltage without current.

The discharge path of the capacitor C1 is thus over resistance R3> Diode D11 Thyristor Th 1 opened, C1 is charged again via resistor R2 and the functional sequence starts all over again. Choosing C1 and R2 will result in the charging pause is specified. By connecting a light-emitting diode LED in series with Thyristor Th1 can be used to display a current flow.

In addition, there are capacitors C3 and C2 in the circuit for interference suppression and a temperature compensation resistor R6 is provided via blocking diode D2 prevents the battery current from flowing back into the circuit - claims - L. e e r e i t e

Claims (6)

Claims 1. Method for fast and long-term charging of gas-tight Nickel / cadmium batteries, in which the battery is in a first charging phase with a constant current of 2 1113 to 4 1113 up to a specified cut-off voltage is charged and the cut-off voltage is dimensioned so that in this charging phase 70 to 90% of the nominal capacity are loaded, characterized in that then a charging pause of the previous period is provided and that nann the accumulator pulsed with the same current strength until the cut-off voltage is reached is recharged, with the ratio between charging pause and pulse duration so dimensioned is that in the reload phase within 24 hours only 10 to 30% of the Nominal capacity can be recharged. 2. The method according to claim 1, characterized in that the Uerhaltnis from charging pause to pulse duration towards the end of the recharging time between 50: 1 and 10 : 1, preferably between ZU: 1 and 30: 1. 3. Circuit arrangement for carrying out the method according to claim 1, characterized in that a constant current source in series with the accumulator (3) (R1 Th1, D3, D4) is switched, which can be controlled via a thyristor (Th1), whose control grid is connected to a timer (R2, C1, Z1) and that in parallel connected to the accumulator (3> a voltage-sensitive arrangement (R5, P1, Th2) is via which the thyristor (Th1) is switched off and the timer in its starting position is reset. 4. Circuit arrangement according to claim 3, characterized in that the voltage-sensitive arrangement contains a thyristor (Th2) whose control grid on the one connected in parallel to the accumulator Voltage divider CR5, P) and the anode of which is connected to the control grid of the thyristor (Th1) 5. Circuit arrangement according to claims 3 and 4, characterized in that in series with the thyristor (Th1) a light-emitting diode (LED) is connected. 6. Circuit arrangement according to claims 3 to 5, characterized in that that it contains a blocking diode (D2).