DE1215247B - Stabilized power supply unit with automatic battery charger - Google Patents

Description

Stabilized power supply unit with automatic battery charger In various portable electrical devices, such as. B. in transistor television receivers, is a power supply from batteries as well as from the public alternating current network intended. This type of power supply can be expanded to include The use of rechargeable batteries also requires a battery charge or buffer tight the network.

High quality battery types, e.g. B. Small accumulators based on lead-sulfuric acid with thickened gelatinous electrolyte, but must after a certain Charging current curve, which in particular overcharges the battery and thus prevents premature consumption of the water reserve of the electrolyte. Fully automatic charging devices have therefore been developed which have the strength regulate the charging current and switch off the device after full charging or switch to a Switch over constant buffer voltage.

Those equipped with semiconductor control elements, for example Devices regulate the charging current depending on the terminal voltage of the battery. The end of the charging process is made dependent on two conditions, namely from reaching a specified terminal voltage per battery cell (e.g. 2.5 volts) and from falling below a likewise predetermined charging current. Two shutdown conditions are taken as a basis because the terminal voltage alone does not have anything to do with indicates the battery's state of charge. The current terminal voltage namely also depends on the size of the respective charging current.

A known circuit for automatic battery charging works as follows: When the device is switched on, the generates a suitable voltage transformed and rectified AC mains voltage on one with the one to be charged Battery series resistance, a voltage drop. This controls a transistor of a bistable multivibrator in the conductive state, so that a second transistor of the flip-flop is blocked. The locked transistor causes a series transistor in series with the battery becomes conductive, as a result of which the full charging current through the battery, the series resistance mentioned at the beginning and an indicator light bulb can flow. Is a certain one around the end of the charge Terminal voltage per cell is reached, a Zener diode, its Zener voltage corresponds to the total terminal voltage of the battery, controlled in the Zener area. This results because the Zener diode is part of a voltage divider in parallel to the battery, a shunt for the charging current and a control of the series transistor, such that the charging current is reduced and the predetermined terminal voltage depending Cell persists. Then the charging current drops to a certain minimum amount from, the voltage drop across the series resistance mentioned first is so small that that the flip-flop falls into the second stable position, the series transistor almost blocked and the charging current is greatly reduced (buffer mode). The reduction in the charging current to a certain value, which is a cell voltage of z. B. maintains 2.3 volts, ensures a second Zener diode in the output circuit of the second transistor bistable flip-flop.

The pure charging circuit described above, however, has a Use in a power supply for the mains, battery, battery charging and battery backup It has several disadvantages: The base-emitter voltage of the first transistor the flip-flop corresponds to the respective voltage drop across the series resistor; at full charging current, the voltage drop can be so great that the transistor may be overloaded or destroyed. Also occur with temperature fluctuations Shifts of the switching point of the toggle switch on. It is also sufficient when applied the charging circuit in a mains-fed power supply unit does not affect the Siebeng the end. Finally, the known means for buffering the battery are also inadequate, because the buffer voltage does not fall below a certain value and another may not exceed the specified value.

The disadvantages described can be avoided by using a electronically stabilized power supply with battery charger that a Contains series transistor lying in series with the charging circuit, which is a Zener diode when reaching the gassing voltage of the battery in the sense of a reduction of the Charging current controls, as well as one through the voltage drop at a series resistor switchable bistable transistor trigger circuit in connection with a second Zener diode to further reduce the charging current when fully charged (buffering) according to the invention The following features are used simultaneously: a) The flip-flop circuit consists of a first transistor whose collector and emitter electrodes are connected to the rectified Voltage and its base electrode is connected to a voltage divider between the end of the series resistor and ground facing the battery are connected, and a second transistor whose base electrode is connected to the collector electrode of the first transistor is connected and in its collector lead .eine Zener diode in series with a balancing resistor that can be switched on for charging or mains operation is included; b) the transistor in series with the battery is controlled by an auxiliary transistor, in the control circuit of which there is a filter capacitor = Bator that can be switched on during mains operation and the emitter electrode of which is connected to ground via T via a resistor; c) with mains operation -the series resistance is bridged, and one of the zener diodes takes over the voltage stabilization; d) The battery is not in use while the mains is in operation Via a diode and a series resistor to the unstabilized DC voltage (buffering).

A resistance of the base voltage divider of the first flip-flop transistor is useful as a resistor with a negative temperature coefficient and the second resistor designed as a setting resistor. It is thereby achieved that the toggle switch still switches over properly even with larger temperature differences and that the current cut-off point for the flip-flop can be regulated precisely, without this - as would be the case with a regulation of the series resistance - a greater power is to be controlled. The for the individual operating data, network operation, battery operation, Battery charging and buffer operation, required switching contacts are after a Another feature of the invention for a switching unit with a "Netzbetrieh" button, a "battery operation" button and a "battery charging operation" button combined.

An embodiment of a power supply part according to the invention for a portable television receiver is in the drawing in the form of a circuit diagram shown.

In the drawing, 1 denotes the terminals for an alternating current source, for example a secondary winding of a mains transformer. Leads from the clamps a connection to a rectifier 2 in bridge circuit, its DC terminals 3, 4 a charging capacitor 5, e.g. B. an electrolytic capacitor, connected in parallel is. A series resistor connects to negative terminal 4 of the rectifier 6, which is connected to the positive via a voltage divider consisting of resistors 7 and 8 Rectifier terminal 3 or ground and that through a contact s1 of a mains operation button can be bridged. A first npri transistor 9 of a bistable multivibrator is located with its emitter electrode at the rectifier-side end of the resistor 6, with its base electrode at the tap of the voltage divider 7, 8 and with its collector electrode via a resistor 10 to ground. The collector electrode of transistor 9 is further connected to the base electrode of a second flip-flop transistor 11, its collector electrode via a zener diode 32nd and one of two parallel-connected Resistors 13, 14 is connected to ground. With a changeover contact s2 either one of the two resistors can be switched on. The emitter electrode of the npn transistor 11 leads to a connection point 15 of a voltage divider, from a resistor 16 connected to the rectifier terminal 4 on the one hand and a Zener diode 17 and a connected in series and connected to ground Resistance 18 on the other hand exists. From the connection between the series resistance 6 and a capacitor 19 connected to ground, a path leads via a switching contact or a resistor 20 that is parallel to it or one that is also connected in parallel Display element 21 to the collector electrode of a pnp series transistor 22. The base electrode the transistor 22 is with the emitter electrode of an auxiliary transistor 23 of the same Conductivity type and via a resistor 24 to ground, the collector electrode with the collector electrode of the transistor 22 and the base electrode via a Switching contact s4 and a capacitor 25 to ground and also to the connection point 15 connected.

The emitter electrode of the transistor 22 leads via a changeover contact s5, a further contact s. and an RC filter element 28 to an output terminal 29 or via another filter element 30 to a second output terminal 31. The output terminals 29 or 31 and possibly other terminals are the power supply connections for the television receiving circuit and possibly also for one in the portable TV built-in FM radio receiver.

Finally, leads from the negative pole of a battery 26 to be charged still via a fuse 27, a contact s7, a resistor 32 and a diode 33 a connection to the collector electrode of series transistor 22.

The switching contacts s1, s4 and s7 belong to a "mains operation" button and the contacts s2, s., 'S, to a "charging operation" button. The switch contact s5 is part of a "battery operation" button.

The mode of operation of the circuit according to the invention in the individual operating modes is as follows: Mains operation of the television receiver (position of the switching contacts as in the drawing) The DC wave voltage obtained by bridge rectification with rectifier 2 is somewhat smoothed by capacitor 5. Since the series resistor 6 is bridged by the contact s1 of the mains operation button, the npn transistor 9 of the bistable multivibrator is blocked because its base potential then becomes more negative than the emitter potential. As a result, the transistor 11 is in the conductive state, and the control voltage for the auxiliary transistor 23 depends on the division ratio of the voltage divider consisting of the resistor 16, the emitter-collector path of the transistor 11, the Zener diode 12 and the trimming resistor 13. With the resistor 13, the breakdown voltage of the Zener diode 12 can be regulated to such a value that the control voltage for the auxiliary transistor 23 and the series transistor 22 coupled to it has a predetermined stabilized voltage of, for example, 12.5 volts at the battery or between the emitter electrode of the transistor 22 and ground. The auxiliary transistor 23 improves the filtering effect of the circuit in connection with the capacitor 25. The contact s "is closed in this operating mode, whereby the resistor 20 and the incandescent lamp 21 are ineffective. The contact s7 is also closed, so that the battery 26 is charged or recharged (buffered) via the resistor 32 and the diode 33 during mains operation. During the operation of the receiver, the battery voltage can have a minimum value of z. B. not fall below 12.9 volts and a maximum value of z. B. do not exceed 14 volts. Battery operation When the power button is triggered and the battery operation button - contact is pressed. in the dashed position - the power for the receiver is provided exclusively by the battery 26. There is a circuit from ground via the battery 26, the fuse 27, the contact, and s6, the filter element 28, the terminal 29, the receiving circuit and back to ground. If the power button has accidentally remained pressed, ie the contact, and s7 are in the switch position shown in the drawing, the battery cannot discharge through the circuit when the power supply component is disconnected from the mains or from the mains transformer, because the diode 33 is then used for the The battery is switched in the reverse direction: battery charging mode When the charging mode button is pressed, contacts s1, s3, s4 and s7 are open, s2 is connected to resistor 14, s. Connects the emitter electrode of transistor 9 to contact s6, and s6 interrupts the connection to the RC -Level 28. During the charging operation, the series resistor 6 is not bridged, so that depending on the level of the instantaneous charging current, a voltage drops that more or less controls the transistor 9 of the bistable multivibrator. As a result, the base bias for npn transistor 11 shifts in the negative direction, ie the transistor is blocked. To the flip-flop it should be said that the resistor 7 has a negative temperature coefficient (NTC resistor), so that the flip-flop circuit even with large Temperature differences switch over properly and that the current cut-off point for the flip-flop can be set precisely with the resistor 8. The blocked transistor 11 allows the Zener diode 17 to become effective, the breakdown voltage of which is selected with the setting resistor 18 so that a certain voltage, e.g. B. 15 volts is not exceeded.

First, the potential of the base electrode of the auxiliary transistor 23 is negative compared to that of the emitter electrode, so that the transistor is driven into the saturation region. This effect is amplified by the series transistor 22, through whose collector-eniitter path the charging current flows. The filter capacitor 25 in the base circuit of the auxiliary transistor 23 is switched off during battery charging by the open switching contact s4, because otherwise the time constant would be too high due to the high capacity of the capacitor (in the order of 1000 @, F). If the terminal voltage of the battery 26 to be charged reaches the gassing voltage (e.g. 15 volts), part of the charging current flows through the Zener diode 17, which then drives the two transistors 23 and 9 in the reverse direction. This reduces the charging current and the previously fully lit light bulb 21 goes out. If the charging current has finally reached a prescribed low value, which corresponds to the full charge of the battery, the voltage drop across the series resistor 6 is so small that the bistable multivibrator is switched to the second stable position in which the transistor 9 is blocked and the transistor 11 directs. At this moment the Zener diode 12 comes into effect, which, in conjunction with the balancing resistor 14, affects the transistors 22 and 23 so that the charging current is not completely switched off, but that a certain buffer voltage is maintained on the battery, a requirement that is met by devices continuously operated from the AC network, such as B. portable television receivers, is important.

Claims (3)

Claims: 1. Electronically stabilized power supply unit with battery charger, which has a series transistor in series with the charging circuit contains, which a Zener diode when reaching the gassing voltage of the battery in Controls meaning a reduction in the charging current, as well as one through the voltage drop at a series resistor switchable bistable transistor trigger circuit in connection with a second Zener diode to further reduce the charging current when fully charged (Buffering), not indicated by the simultaneous use of the following Features: a) The flip-flop consists of a first transistor (9) whose collector and emitter electrode on the rectified voltage and its base electrode on a voltage divider (7, 8) between the one facing the battery The end of the series resistor (6) and ground is connected, and a second transistor (11), des-. sen base electrode with the collector electrode of the first transistor (9) is connected and in its collector lead a Zener diode (12) in series with a balancing resistor that can be switched on for charging or mains operation (13, 14) is included; b) controls the transistor (22) in series with the battery an auxiliary transistor (23), in the control circuit of which a switchable during mains operation Filter capacitor (25) and its emitter electrode via a resistor (24) connected to ground; c) during mains operation, the series resistor (6) is bridged, and one of the Zener diodes (e.g. 17) takes over the voltage stabilization; d) During mains operation, the battery (26) is connected to a diode (33) and a Series resistor (32) on the unstabilized DC voltage. 2. Power supply part according to claim 1, characterized in that a resistor (7) of the base voltage divider of the first flip-flop transistor (9) as a resistor with a negative temperature coefficient and the second resistor (8) is designed as a setting resistor. 3. Power supply part according to claim 1 or 2, characterized in that the transistors of the flip-flop (9, 11) of the npn type and the auxiliary transistor (23) and the series transistor (22) are of the pnp type. 4.. Power supply part according to claim 1 or the following, characterized in that a switching unit with a mains operation button (s1, s7), a battery operation button (s5) and .einer battery charge button (s2, s3, s) is provided . References considered: British Patent No. 892,954; Brochure no.68 "Dryfit transistor switch" from the company Akkumulatorenfabrik Sonnenschein from April 1st, 1964, pages 17 to 20.