DE2924851C2 - "Circuit arrangement for the regeneration of an operating hours counter for electrical household appliances" - Google Patents

Description

The present invention relates to a circuit arrangement for the regeneration of an operating hours counter for electrical household appliances, such as extractor hoods, coffee machines, hot water devices, dishwashers and the like, which gives a signal after a certain operating time, which is connected in parallel to the monitored consumer and in the discharge current direction via a high-resistance discharge resistor an electrolyte cell is fed with direct voltage.
An operating hours counter of the above type is known from an older proposal, in which the display of the permissible operating time is carried out by destroying the electrolyte cell and making it clear. The electrolyte cell must then be exchanged and replaced with a new one.

The monitored household appliances should at this recognizable point in time with a new fat or Odor filters (extractor hoods) or vapor filters must be fitted, or they must be descaled or decalcified. Reservoirs need to be filled.

From Electronics magazine November 16, 1964, pages 67-71 is a reversible electrolyte cell known.

This known cell is intended to record time lapses.

Based on this, the invention is based on the object of specifying a circuit arrangement which charging and discharging of the electrolyte cell according to the time requirements of the operating hours counter allowed

■) 5 To solve the problem, the invention proposes that the Electrolyte cell in the direction of the charge current via a monostable flip-flop and one in relation to the Discharge resistor is fed to the small charging resistor, so that the electrolyte cell after its discharge briefly by reversing the current flow against the Discharge current direction can be operated, with a relatively high current flowing that the charging circuit up at the time of the largely completed discharge of the electrolyte cell is electronically blocked that for Start of the charging process in front of the monostable multivibrator, a pushbutton switch is arranged that with the Resistor and the electrolyte cell is connected to the base of a transistor that controls the electronics, as soon as the electrolyte cell is largely discharged and the voltage drop across the electrolyte cell including the downstream charging resistor is greater than 0.7 volts, and that the collector of the transistor via a resistor to the positive pole of the DC voltage source is placed that the emitter of the transistor is connected to ground, and that a light-emitting diode is provided, whose The output is connected to ground and its input from the collector of the transistor via a non-element and a Resistance is controlled so that the light emitting diode after

The specified operating time has expired.

The electrolyte cell with, for example, a silver cathode and a gold anode is suitable for a Operating time from 300 to 500 hours to be monitored, with a power failure saved by reloading Data does not delete

By reversing the current flow after the corresponding operating time has been displayed under Simultaneous increase of the current between the poles of the electrolyte cell can in a short time the cell can be regenerated so that it is ready again to monitor and measure the operating hours

There is no need to change the cell.

After the expiry of the required operating hours has been displayed, the tipping level and thus the Reversal of the current flow triggered and reset after a preselectable charging time. The electrolyte cell is then ready for operation again To prevent the When the charging process is running, the charging circuit is electronic before the Eiektroiyt-Zeiie is largely discharged blocked

The pushbutton switch is arranged at the start of the charging process

The charging circuit is blocked as long as the voltage drop across the electrolyte cell and the Charging resistance is greater than 0.7 volts

For precise setting of the switching point, it is advantageous if there is a in front of the base of the transistor Threshold switch, e.g. B. switched a Schmitt trigger is

Another detail is that the series resistor connected to the input of the flip-flop is coupled, is connected to ground, this input also via a normally closed pushbutton switch on the positive pole the DC voltage source

It is also advantageous that the flip-flop has a timing element for the timing of the charging process is coupled. A detail is characterized in that the flip-flop consists of two NAND gates consists of one of which is controlled by the push button switch and the output of the other NAND element, with between the output of the first NAND gate and the input of the second NAND gate the capacitor of the timing element is connected, the resistance of which is connected to ground as well as the emitter of the transistor and that the flip-flop is designed as an IC because by changing the operating voltage of the monitored Consumer, e.g. B. an extractor hood, the speed of which is controlled, it is advantageous to this To detect operating voltage change in the monitoring circuit, which happens because the AC input voltage is fed in via a transformer, while the discharge resistance is above a diode is connected directly to the positive pole of the secondary side of the transformer, the series resistor of the Collector is connected to the positive pole of a bridge rectifier connected on the secondary side, which is also coupled to the pushbutton switch

An embodiment of the invention The circuit is shown in the drawing and briefly explained below

The primary side of a transformer Tr \ is connected in parallel to the consumer circuit (not shown)

Usually the control range is the AC voltage in the consumer circuit between 100 and 220 volts.

A bridge rectifier Vi is on the secondary side

which feeds the control circuit, while a second circuit is also connected on the secondary side, which via a diode V7 and a high-resistance discharge resistor A4 (e.g. 22 MΩ), an electrolyte cell V 4 feeds a silver cathode, a gold anode and electrolyte contains

The charged cell V4 is slowly discharged depending on the consumer circuit (approx. 350 hours). The transformer Tr 1 is designed so that

ίο with an input voltage of 220 volts about 8 volts Output voltage can be achieved.

During the discharge process, the current flows through the diode VT, the discharge resistor R 4 and the E-cell V4 from point 2 to point 1. With NIGHT-GIied V9 there is 0 potential at the output, so that point 1 is connected to ground

The base of a transistor VS is connected to point 2 of the Ε-cell V4, the transistor V5 being blocked until the Ε-cell V4 is so largely discharged that the Γ · * · hwell voltage of 0.7 Voit on the transistor V5 Then the transistor VS looks through it and uses a light-emitting diode V6 to visually indicate that the maximum operating time of the monitored device has been reached.

The light diode V6 is in a circuit that connects from the positive pole of the bridge rectifier Vl via a series resistor RS (e.g. 100 Ω), a NOT element V 8, another series resistor R 6, diode V6 to the negative pole of the bridge rectifier Vi runs In addition, the collector of the transistor V5 is connected to the series resistor R 5, the emitter of which, like the output of the light-emitting diode V6, is connected to ground. If the transistor V5 turns on, the diode V6 lights up. The input of NOT element VS is then connected to ground potential. The output of V8 is therefore positive. The diode V6 goes out when the transistor VS is blocked, because at the input of Vi there is then a + signal at the output but a - signal.

If the diode V 6 lights up and only then can

by pressing a break button switch 7 * 1, which is connected upstream of a monostable multivibrator MK , which is controlled by the bridge rectifier Vi, the

Can be started. To determine the charging time, the flip-flop MK

coupled to an ÄC member R 2, C2

When the transistor VS is switched on and the multivibrator MK is started, there is a positive voltage at point 1 of the Ε cell V 4 , so that a current flows through a NOT element V9. via the charging resistor R 3 (approx. 3ΚΩ), the

so Ε-cell V4 from point 1 to point 2 and the base-emitter path of transistor V5 takes place against zero potential

When the charging process is complete, the LED V6 goes out.

It is then present at the output of the electronics, which is preferably designed as an IC, at V9 zero potential and therefore also at point 1 of the E-cell V4.
The unloading process can now proceed again.
It must still be sewn that a smoothing capacitor C1 is connected downstream of the bridge rectifier V 1. Furthermore, the discrete components of the monostable multivibrator MK are two NAND elements V 2, Vi.

The components V2, V3, V9 can be combined to form an IC.

One input of the NAND element V3 is connected on the one hand to + via the push button switch 7 * 1 and on the other hand via a series resistor R i -, while the other is connected to the output of the NAND element V2.

stciieri will. F. in the input of the NAND element V2 is controlled via R 2. the; in -, and the output of V 3 via C2 , while the other is controlled with an inverted + signal. The output of V2 controls NOT GIied V9. The circuit shown is only an example and can be varied in many ways within the scope of the invention.

1 sheet of drawings

Claims (7)

Patent claims: t. Circuit arrangement for the regeneration of an operating hours counter for electrical household appliances, such as extractor hoods, coffee machines, hot water devices, dishwashers and the like, which gives a signal after a certain operating time, which is connected in parallel to the monitored consumer and an electrolyte cell in the direction of the discharge current via a high-resistance discharge resistor is fed with direct voltage, characterized in that the electrolyte cell (VA) is fed in the direction of the current flow via a monostable multivibrator (MK) and a charging resistor (R 3) which is small in relation to the discharge resistor (RA) , so that the electrolyte cell ( VA) can be operated briefly after its discharge by reversing the current flow against the direction of the discharge current flow, with a relatively high current flowing so that the charging circuit is electronically blocked until the electrolyte cell (VA) is largely discharged, that at the start of the charging process a pushbutton switch (Ti) is arranged in front of the monostable flip-flop (MK) that with the resistor (RA) and the electrolyte cell (VA) - the base of a transistor (VS) is connected, which controls the electronics as soon as the electrolyte Cell (VA) largely discharged and the voltage drop across the electrolyte cell (VA) including the downstream charging resistor (R 3) is greater than 0.7 volts, so that the collector of the transistor (V5) is connected to a resistor (RS) the positive pole of the sliding voltage source is placed, that the emitter of the transistor (VS) is connected to ground, and that a light-emitting diode (V6) is provided, the output of which is connected to ground and the input of which is connected to the collector of the transistor (VS) via a non-element (VS ) and a resistor (R 6) is controlled so that the light emitting diode (V6) lights up after the specified operating time. 2. Circuit arrangement according to claim 1, characterized in that in front of the base of the transistor (VS) a threshold switch, ζ. Β. a Schmitt trigger is switched 3. Circuit arrangement according to claim 1 or 2, characterized in that the series resistor (R 1), which is coupled to the input of the flip-flop (MK) , is connected to ground, this input also via an NC push button switch (TX) on positive pole of the DC voltage source. 4. Circuit arrangement according to claim 1 to 3, characterized in that the flip-flop (MK) is coupled to a timing element (C2, / 72) for the timing of the charging process. 5. Circuit arrangement according to claim 1 to 4, characterized in that the flip-flop (MK) consists of two NAND elements (Vl, K3), one of which (V ¹ S) from the push button switch (TX) and from the output of the other NAND element (V2) is controlled, the capacitor (C2) of the timing element (R 2, C2) being connected between the output of the first NAND element (V3) and the input of the second NAND element (V2) , the resistor (R 2 ) as well as the emitter of the transistor (VS) is connected to ground. 6. Circuit arrangement according to claim 1 to 5, characterized in that the flip-flop (MK) is designed as an IC. 7. Circuit arrangement according to Claim 1 to 6, characterized in that the input AC voltage is fed in via a transformer (TrX), the discharge resistor (R 4) being placed directly on the positive pole of the secondary side of the transformer (Tr X) via a diode (Vl) is, the series resistor (RS) of the collector is connected to the positive pole of a bridge rectifier (VX) connected on the secondary side, which is also coupled to the push button switch (Ti)