DE2529633A1 - Control circuit for battery state indication - has current supply path with pulse feedback in signal frequency rhythm on high ohmic battery state - Google Patents

Abstract

The control circuit is particularly intended for an alarm clock battery and uses a pulse generator for actuating a control transistor. With the battery attaining a high ohmic state, the pulses appearing in the rhythm of the signal frequency are fed back in such manner that a time changing effect is produced at the previous stages. Preferably the pulse generator is of astable type and is affected via a capacitor, while the control transistor may be also energised directly. The transistor may be biased and may be energised at its base via a capacitor connected with the supply line.

Description

Control circuit for a battery status indicator The invention relates to a control circuit for the display of the battery status of a battery-operated Device, in particular an alarm clock, with a control transistor via a pulse generator is influenced in such a way that the subsequent signal generator within a emits an intermittent tone sequence for a certain period of time.

In the case of battery-operated devices, it is important that the user informs them in good time can recognize the used condition of the battery. In particular, this is a control option required for alarm clocks, as a sudden failure is not always noticed in time can be.

In the DOS 2306545 a control circuit for a battery was introduced described that these known disadvantages by a voltage-dependent additional switching stage partially avoids, but still has the disadvantage that If the batteries have become high-resistance, the desired display function fails.

Efforts have been underway lately to discover the overall characteristics of one modern alarm arrangement with automatic repetition etc.

to unite in an integrated circuit; there is also one As perfect a battery status display as possible is desirable.

To avoid these disadvantages, the invention has the task of providing a Control circuit of the specified type to provide a clear indication of the state of charge of the battery.

According to the invention this object is achieved in that the in the power supply branch in the case of a high-resistance battery that occurs in the rhythm of the signal transmitter frequency Pulses are fed back so that at the previous stages a time-changing Effect is achieved.

The proposed circuit should preferably be integrated in an Find circuit use. It turned out that the power consumption almost only is determined by the tone generator. Automatic alarm circuits can be used in can be realized in both analog and digital technology.

In the analog version, an astable generator controls (e.g.) the Tone generator in such a way that with a normal battery an intermittent Tone sequence results.

Is by the inventive circuit arrangement as a result of a discharged and high-resistance battery of the astable generator from the The supply line influences the impulses generated by the signal generator, the intermittent tone sequence changes to a continuous tone, which the user (e.g.) of the alarm clock indicates that the battery can only be used for a short time.

Wake-up systems with automatic repetition are known; the alarm process is initiated with a relatively short signal duration; it follows a rel. Long Break (e.g. 5 min.), Which becomes shorter and shorter within 10 - 12 min Final state into an intermittent tone sequence of e.g.

0.5 sec. On / 0.5 sec. Off to move on.

This energy-saving signal output is not a requirement; as a final state a continuous tone can also be used or desired.

The display of a discharged battery can then according to the invention be done in that controlled on continuous tone at the beginning of the alarm process becomes what the user must inevitably notice.

There are also automatic alarms # chaltunge? I that are based on digital Work base. A number of settable flip-flap levels are via logical links influenced one after the other in such a way that the desired shortened tone sequence is produced.

In this case, according to the invention, with an increased internal resistance the battery is an indication that a normally non-existent logical constellation through an additional capacity from the supply line to a dynamic separation of a part or a memory flip-flop achieved with the result that if the battery is used up, the start of the WecK process a short tone sequence or, as in the example shown, a continuous tone is generated.

In another development according to the invention, a known, digitally controlled time reduction in such a way that the Used battery makes noticeable by increasing the internal resistance.

The embodiments of the Brfindu.1g are based on the Drawings described in more detail. The figures show: FIG. 1 a block diagram for an automatic wake-up device on an analog basis.

2 shows a block diagram of a digital automatic wake-up device.

Fig. 3 shows an embodiment of the invention in an alarm clock, wherein an astable generator is used as the pulse generator.

Fig. 4 shows a further embodiment, where the control transistor, which controls the signal generator, is influenced according to the invention.

5 shows a further exemplary embodiment of an automatic alarm system with a time reduction on a digital basis FIG. 6 shows another digitally implemented circuit which incorporates the inventive Application shows.

7 shows the temporal relationships between the possible signal pulses in Connection with the modified signal output according to the invention.

In Fig. 1, an electronic wake-up system is shown, its signal generator 1 is connected to the battery 5 via the supply lines 6j7 and switch 9 is.

The signal generator can either be connected by self-excitation be controlled with a control coil or by external excitation. The inventive Function can be achieved with both principles. The illustrated embodiments were carried out in self-excitation.

The control stage 2 can be designed in one or more stages; she cares for starting or stopping the signal generator.

Level 3 and possibly level 4 ensure the desired signal profile, as shown e.g. in Fig. 7a and 7c.

The resistor 8 represents the internal resistance of the battery Current flow of the signal generator 1 can be via the supply lines 6 and 7 at the resistor 8 a voltage drop that is lost to the usable supply voltage and a pulsating DC voltage is generated.

For a better understanding it should be mentioned that signal generators of the initially mentioned type only carry electricity in about 20 - 50% of the period time; the rest Time period is de-energized.

The known circuit according to FIG. 2 operates on a digital basis.

A clock generator 10, whose function may be from the clock drive system can be accepted, controls the divider 20 so that at the output a - e pulses with the time sequence (e.g.) 4 '/ 2' / 1 '/ 30' '/ 15' 'etc. can be removed.

A decoding matrix 14 not described in more detail sets in the desired Follow the memory flip-flop 13 and activate stages 12 and 11, which start with 1/2 1 are identical.

titer the unspecified reset input R becomes the Memory after (e.g.) 1 sec. reset again (see Fig. 7 c).

If the internal resistance of the battery is increased, it will be in the same way as already Described in Fig. 1, a pulsating DC voltage on the supply lines stand; their pulse sequence corresponds to the tone frequency (e.g. 1 Khz).

3 shows an analog embodiment according to the invention.

The signal generator is through the work coil 22, the control coil 22 a, the excitation transistor 23 C 38 and R 39 formed.

The tax level is formed by T 24, R 27 and R 28.

The astable generator with the two transistors 26/35 works in a known way and controls intermittently via R 28 I 24 (e.g. 0.5 sec. On, 0.5 sec. The end).

If the internal resistance of the battery 25 increases, the supply line is connected the mentioned impulses; they trigger the astable generator via the capacitor 34 so that it no longer works with the example given previously (0.5 sec. on, 0.5 sec. Aus) swings, but with the Audio frequency - what the consequence has that a continuous tone is produced.

In FIG. 4, which is based on the same circuit as in FIG in a further example, the control transistor is influenced according to the invention. Of the Voltage divider 34 b / 34 d is dimensioned so that the transistor 34 a only in connection with the pulse voltage that is fed to the base via the capacitor 34 c, is controllable and the then charged capacitor on the signal generator Continuous tone controls; this is the case with a high-resistance battery.

With a normal and therefore low-resistance battery, this pulse component is missing, and the control transistor 24 receives its control signal via the resistor 28 from astable pulse generator that works in the seconds range and the capacitor 34 e not affected because the time constant 34 f / 34 e is in the msec range (e.g. signal generator frequency 1 Khz).

5 shows an example according to the invention, executed digitally. The already known functional sequence has already been explained with FIG. 2.

In the case of a used battery that has become high impedance the pulses pending on the supply line to the divider via a capacitance 34 20 is supplied at a point which corresponds to an edge-controlled set input and already has a relatively low frequency. The incoming via the capacitor 34 Pulses increase the output frequency at Q (20) so that the automatic repetition, which normally runs according to the timing diagram 7c, a much faster one Sequence (e.g. by a factor of 60, as 7d shows).

This change in the pulse sequence over time will be noticed by the user. In a modified embodiment according to the invention, the memory flip-flop 13 influenced. Usually continues the trailing edge, which is marked with R at 7 c / 7 d and is assigned to the 1 second control pulse, via line 44 the flip-flop 13 back again.

In the case of a high-resistance battery, 13 is over 34 h with a clock frequency of e.g. 1 Khz, so that via the output Q, the gate 43 and the resistor 28 the control transistor 24 is influenced so that the signal generator emits a continuous tone gives off, which is also noticeable compared to the normal pitch.

The start of the alarm time is marked with t 1 (Fig.

The capacitors marked with 34 can optionally be used in an integrated circuit can be formed by a junction capacitance.

Another application example according to the invention is shown in FIG known digital wake-up system is after closing the switch 19 on the with 65 marked set input of the memory flip-flop 51 set in action. Briefly opening the button 50 via the reset input 64 of the memory 51 reset; the whole alarm system is then switched off.

The circuit works as a wake-up memory.

This known system has the advantage that it is used in an alarm clock the mechanical effort can be reduced to a minimum.

According to the invention, as a result of a used battery pulses pending on the supply line are amplified in transistor 61 and over the differentiating element 57/56 and the diodes 54/55 are fed to the memory 51.

The pulses coming through the differentiating element trigger the bistable Memory 51 in the rhythm of the signal generator frequency. Be on line 52 the triggerable stages 20 and 13 (FIG. 5) controlled with this relatively high frequency; the signal generator emits a continuous tone.

In the embodiments shown so far, existing Circuit units are also used to achieve the effect according to the invention.

In a last, not specially marked application example the pulses mentioned in FIG. 6 via the diodes 54/55 become a separate catch flip-flop (Batschflipflop), which after the first pulse at the clock input in a defined State remains and then controls the control transistor (24) in the on position.

After inserting a new battery, the impulses disappear the diodes 54/55, and the flip-flop is inoperative.

The additional components required for the function according to the invention can be integrated into an electronic wake-up system without significant additional effort.

The exemplary embodiments shown were primarily based on an NPN structure the end. In the case of a PNP structure, the pulses are transmitted to the Ninus supply line accepted.

The signal change can also be compared to the exemplary embodiments shown in the opposite way, so that the normally present continuous tone when used Battery changes to an intermittent tone sequence. This signal change is suitable for typical warning systems; optical signal generators are then also suitable.

P a t e n t a n S p rü c h e =============================== 1. Control circuit for displaying the battery status of a battery-operated device, in particular an alarm clock, a control transistor being influenced by a pulse generator; characterized in that the in the power supply branch has become high resistance Battery in the rhythm of the signal frequency occurring pulses are fed back so, that a time-varying effect is achieved at the preceding stages.

2. Control circuit according to claim 1, characterized in that an astable pulse generator (55/26 via a capacitance (34) is influenced.

3. Control circuit according to claim 1, characterized in that the control transistor (24) is influenced directly.

4. Control circuit according to Claims 1 and 3, characterized in that that a biased (34 b / 34 d) transistor (34 a) via one to the »supply line connected capacitor (34 c) is affected at the base.

5. Control circuit according to claim 1, characterized in that a divider (20) is also influenced.

6. Control circuit according to claim 1 and 5, characterized in that that the divider (20) is influenced by a capacitance (34).

Claims (1)

7. Control circuit according to one of the above claims, characterized in that that a flip-flop (13) used as a memory is influenced. 8. Control circuit according to one of the above claims, characterized in that a flip-plop serving as a memory (13) is influenced by a capacity (34 h). 9. Control circuit according to claim 1, characterized in that a wake-up memory (51) is influenced. 10. Control circuit according to claim 1, characterized in that a catch flip-flop is impulsively influenced only via the supply line. 11. Control circuit according to one of the above claims, characterized in that that acoustic devices are used as signal generators. 12. Control circuit according to claim 1 - 10, characterized in that that op # ical devices are used as a signal generator. Blank page