DE102007053298A1 - Circuit arrangement for identifying switch-on sequences for on/off switch of e.g. LED-torch light, has capacitor discharged via discharge resistor with defined time constant and charge time constant, when arrangement is switched off - Google Patents

Abstract

The arrangement has a module (11) with a flip-flop (50), a capacitor (C8) charged by a voltage supply (3) via a diode (D8), and a charging resistor (R9) charged with a charge time constant via an on/off switch (S) when the switch is switched on. The charging voltage is fed via another capacitor (C9) and is applied to a switching input of the flip-flop via another diode (D9). The capacitor (C8) is discharged via a discharge resistor (R3) with a defined time constant and the charge time constant that is less than the defined time constant, when the arrangement is switched off. An independent claim is also included for a method for controlling different states of loads, where the states are connected within a certain time span by switching an on/off switch off and on.

Description

circuitry for detecting switch-on sequences for an on / off switch.

Technical area

The The invention relates to a circuit arrangement for detection of switch-on sequences for an on / off switch, equipped with a first module, the includes a flip-flop for outputting a status signal.

State of the art

It There are applications where the consumer is out of energy saving or hard for other reasons On or Off is switched on. Therefore, these devices do not have a "stand-by mode", so the controller various modes of operation a single on / off switch is difficult.

So far were for different modes used when switching mechanical tap changer. These either switch through different phases, which then go to the consumer be placed next to the on / off function of the switch various signals switched and for evaluation to the consumer fed. In many applications, z. B. in existing installations, but are not appropriate Tap changer available, but only normal on / off switches, which or switch off. Here, the switch is often only as a signal switch used, and the consumer nonetheless permanently to the power supply connected so that he is able to get the switch delivered by the switch To process signals. However, this attracts increased power consumption by itself, the disadvantages increased Operating costs result. For electrical appliances, it is possible mechanical However, these are very expensive and error-prone to use tap changer.

task

It is therefore an object of the invention, a circuit arrangement for detection of switch-on sequences for specify an on / off switch equipped with a first module is that includes a flip-flop for outputting a status signal. It is also object of the invention to provide a method by means of which such power-up sequences can be detected.

Presentation of the invention

The object is achieved by a circuit arrangement according to claim 1. The circuit arrangement is simple and can be used in many different areas. According to the invention, a first capacitor C8 of a first module is switched on via the on / off switch when switching on 11 Charged via a charging resistor R9 and a first diode D8. This charging voltage is passed through a second capacitor C9 and passed through a second diode D9 to the switching input of a flip-flop. The flip-flop may consist of a logic gate, but it may also be implemented discretely. The flip-flop is designed so that it assumes a defined state in the absence of input signal.

Becomes now the on / off switch after a longer off time again turned on, so are first all capacitors discharge and therefore charge up quickly. Thereby a high voltage change rate arises at the first capacitor C8, the above the second condenser C9 and the second diode D9 into a pulse is converted, which switches the flip-flop, and at the first output A1 of the flip-flop thus a status signal is available.

To Turning off the on / off switch, the first capacitor C8 via a Resistor R10 is discharged slowly and in a defined manner. Will now be the on / off switch pressed again after a short time and thus closed, so much is in the first capacitor C8 Load saved. The capacitor charges accordingly slower on, and the lower voltage change rate causes over the second capacitor C9 and the second diode D9 only a small pulse is placed on the input of the flip-flop, which is not able to switch this. Since no input signal is present at the flip-flop, it falls into a defined state, by a suitable dimensioning the resistances R3 and R4 and the presence of C10, which are the two exits of the Flip flops in discrete version with connect the power supply is reached. By the additional Voltage pulse via D9 becomes the second input of the flip-flop, "come up faster," and the flip-flop is thus in a different switching state than when switching the circuit after a longer Break.

The circuit of the first module 11 So it makes it possible to detect whether the device in question is switched on again after a longer switch-off time, or whether it was switched off and then switched on again only briefly. If several of these circuits are connected in series via switches, different consumers can be switched on / off via simple on / off operations or a consumer can be switched to different modes.

Short description of the drawing (s)

1a Circuit diagram of the circuit arrangement according to the invention in a three-stage embodiment.

1b Circuit diagram of an embodiment of several directly connected to the circuit arrangement according to the invention consumers.

2 Simple evaluation logic to switch different consumers on and off in succession.

3 Some relevant signals to describe how a module works.

4 Logic and state diagram of the different switching stages.

Preferred embodiment of invention

1 shows a three-stage embodiment of the circuit arrangement according to the invention. An on / off switch S becomes a voltage transformer 3 On and off, which supplies the circuit arrangement according to the invention with voltage. The voltage converter is supplied by an input voltage UE. The input voltage may be a DC or AC voltage, for. B. a mains voltage.

As soon as the on / off switch is turned on, a first capacitor C8 is charged via the series connection of a first diode D8 and a first resistor R9 with a defined first time constant τ1. The time constant is small and charging is therefore fast. This is good in 3 to recognize in which the signal 22 represents the voltage across the first capacitor C8. If the on / off switch is switched off again, the first capacitor is again discharged via a resistor R10 connected in parallel with a second defined time constant τ2. This time constant is significantly greater, so that the unloading process takes a significantly longer time. When the on / off switch is first switched on, the charging voltage of the first capacitor C8 is conducted via a second capacitor C9 and a second diode D9 to the input E1 of the flip-flop. Since the first capacitor C8 charges very fast, this generates a pulse at the second diode D9 242 , which brings the downstream flip-flop for switching. The status signal at the output A1 of the flip-flop is logic 0 and can be evaluated accordingly.

If the on / off switch is switched off, the second capacitor discharges via the discharge resistors R10 and R11, and the first capacitor C1 discharges via the discharge resistor R10. If the ON / OFF switch is only turned off for a short period of time and then immediately turned on again, like the signal 20 in 3 represents, the first capacitor C8 discharges only very little, as from the signal 22 can be seen in this figure. When restarting, therefore, a charging current flows only for a short time, and the voltage change at the first capacitor is relatively low, resulting in a very small voltage pulse 244 at the diode results. This pulse is not high enough to switch the flip-flop. By means of a suitable dimensioning of the resistors R3 and R4, which connect the outputs A1 and A4 to the voltage supply, it is achieved that the flip-flop is defined when the input signal is missing in a state in which the output A1 is logic 1.

The signal 26 in 3 sets the current through the second diode; D9. It is good to see that when the device is first turned on, a high current pulse flows through the diode, resulting in the switching of the flip-flop, while no current flows after being briefly switched off and on because the voltage across the diode is less than their flux voltage. The signal 26 represents the voltage across a third capacitor C10. This is needed to get a defined turn-on sequence from the flip-flop. The signals 27 and 29 represent the voltages across resistors R6 and R5, which represent the state of the associated outputs A1 and A4.

Thus, with the circuitry of the module 11 two different state variants are displayed. Once the state in which the first output A1 is logic 0, and the appearance when the circuit is powered after prolonged off power. If the circuit is only briefly switched off and on, the first output A1 is at logic 1.

According to the invention, several of these modules are connected in series via controlled switches in order to obtain different state signals. The switches are controlled by the respective output signal of the preceding module. The desk 12 , the second module 13 switches, so is from the output A1 of the first module 11 driven. The desk 14 of the third module 15 is from the output A2 of the second module 13 driven.

This As a result, after each short on / off of the switch S, ie the voltage supply of the inventive circuit arrangement, another module is "turned on", so its first output is at logical 1. This allows different states of a Consumer, or it can be different consumers be switched.

For example, by means of the three outputs A1-A3 a control gear for lamps can be controlled, that corresponding to the three state signals 31 . 33 and 35 sets different dimming levels of the lamps.

In order to clarify the exact mode of operation of the interconnected modules is in 4 a signal and a state diagram of the switch S and the first outputs A1-A3 of the modules are shown. If, at time t1, the switch, and thus the power supply, is switched on, the flip-flop of the first module switches 11 as described above, in a state where the first output A1 is at logical 0. This leaves the electronic switch 12 switched off, and the power supply of the other modules as well.

This is also reflected in the state diagram 41 low. At time t ₀ , all is switched off, that is, the switch S and the first outputs A1-A3 to logic 0. If the switch S is turned on, as described above, all first outputs A1-A3 remain at logic 0. Since all the second outputs are A4-A6 to logical 1. This can be used to B. turn on all consumers.

The system can be switched off again at any time by the switch S. But if, as at time t3, only briefly and immediately turned on again, the flip-flop of the first module oscillates 11 um, and the output A1 is at logical 1. This causes the second module 13 is turned on. For the second module, it is but a switch on after a long break, since it was previously switched off. Thus, the first output A2 of the second module remains at logic 0. In the state table 41 At time t ₃ , therefore, the switch S and the first output A1 of the first module to logic 1. The signals can be evaluated accordingly to operate a consumer in another state. For several consumers z. B. be switched off, since now the second output A4 of the first module 11 is at logical 0. This is z. B. the consumer 17 in 1 the case. If the output A4 is set to logical 1, the LED driver is switched on, the output oscillates to logical 0, the driver and thus also the LED D5 is switched off. The consumers 18 and 19 remain switched on in this state, since the second outputs A5 and A6 of the modules 13 and 15 are still at logical 1.

If the switch S is switched off again for a short time and switched on again at the time t ₅ , this is now also the case for the second module 13 a short off and on again, so the first output A2 of the second module oscillates to logical 1. This is the third module at this time 15 The first output A3 of the third module remains at logic 0 so that at the time t ₅ the two consumers remain 17 and 18 switched off, only the consumer 19 is still switched on.

If the switch S is briefly switched off again and switched on again at the time t7, this is now also the case for the module 15 a short off and on again, and the first output A3 of the third module oscillates to logic 1. Thus, all the first outputs to logic 1, and all second outputs to logical 0. In the example of the embodiment according to 1 Thus, all consumers would be switched off.

The circuit according to the invention can remain switched on for any desired length of time. As long as the modules are supplied with power, their condition does not change. Decisive are the shutdown breaks. If the shut-off pauses are short, a state is incremented each time it is switched on again. The last possible state remains with repeated switching off and on, as shown in the logic diagram in 4 is apparent. If the shutdown break is longer, the circuit is reset and starts again at the first state. After switching off and on again, the circuit is therefore in the "second" state, in which S and A1 are at logic 1.

Of course, the signals of the outputs and of the switch can be further connected in order to achieve a specific behavior of the circuit. Should z. B. in each state only a certain signal to be logical 1, the z. B. represents a dimming stage, so the signals according to the circuit in 2 be linked. This is constructed with simple AND gates and inverting Schmitt triggers, and switches outputs Z1-Z4 according to the states after the row. This can be switched through the logic table 43 be removed. When switching on for the first time (after a long pause), the output Z1 is at logic 1, at the second switch-on (after a short switch-off) the output Z2 and so on. Naturally, any other behavior can be achieved with other logic circuits.

By such a design, the circuit according to the invention z. B. can be used to produce in an old house installation by means of only a light switch only by briefly switching off and on again different lighting scenarios. The circuit according to the invention can also be used to ver in electrical appliances with only a simple switch to establish different states. This is advantageous for z. Example, in an LED flashlight, in which all LEDs are turned on in the first state when first turned on. After switching off and on again, some of the LEDs are switched off, etc. Thus, depending on the number of interconnected modules, different dimming positions can be switched. The big advantage of the circuit is that it can be switched off again at any time without switching through all states, as is the case with a mechanical multiple switch. This significantly improves the usability of the device.

Claims (11)

Circuit arrangement for the detection of switch-on sequences for an on / off switch, with a first module ( 11 ), which is a flip-flop ( 50 ) for outputting a status signal, characterized in that via an on / off switch (S) when switching on a first capacitor (C8) of the first module ( 11 ) by a power supply ( 3 ) is charged via a first diode (D8) and a charging resistor (R9) with a charging time constant (τ1), and this charging voltage via a second capacitor (C9) out and via a second diode (D9) to the switching input of the flip-flop ( 50 ), whose first (A1) and second (A4) output then output corresponding state signals for evaluation, wherein the first capacitor (C8) is discharged again with a switched-off circuit arrangement via a discharge resistor (R3) with a defined time constant (τ2) the charging time constant (τ1) of the first capacitor is significantly smaller than its discharge time constant (τ2). Circuit arrangement according to Claim 1, characterized that also a load to be controlled with the on / off switch on or is turned off. Circuit arrangement according to one of Claims 1 or 2, characterized in that the circuit arrangement comprises a second module ( 13 ) with an identical circuit, wherein the second module via an electronic switch ( 12 ) through the first module ( 11 ), and the activation of the second module ( 13 ) via the first output (A1) of the flip-flop of the first module (A1) 11 ) he follows. Circuit arrangement according to one of the preceding claims, characterized in that the circuit arrangement further modules ( 15 ), each with electronic switches ( 14 ) are driven by the first outputs (A2) of the previous modules. Circuit arrangement according to one of the preceding Claims, characterized in that the status signals (A1 .. A6) of the Modules to evaluate a load by simply short-circuiting and switching the switch S back to different states, where the states simply by briefly switching the switch off and on again S be switched on. Circuit arrangement according to one of the preceding claims 1-4, by in that the status signals (A1 .. A6) of the modules are evaluated be to several loads by simply short off and on again individually on and off to be able to switch by simply short Switching the switch S off and on again switches a state on and assigns a switch-on pattern of the loads to each state is. Circuit arrangement according to one of the preceding Claims, characterized in that the maximum period between the Switching the switch off and on again <5 s to advance to a state. Method for controlling various states of a or more loads, characterized in that the states by simple switching off and on again of an on / off switch (S) be switched through within a certain period of time. A method according to claim 8, characterized in that the maximum period between switching off and on again of the switch for switching through the states 5 Seconds. Method according to one of the preceding claims, characterized characterized in that the load at any time by turning off the switch S can be turned off. Method according to one of the preceding claims, characterized characterized in that the states for a longer time Switching off the switch reset become.