CH666771A5 - CIRCUIT ARRANGEMENT FOR AN ELECTRONIC RADIO CONTROL RECEIVER. - Google Patents

Description

DESCRIPTION The invention relates to a circuit arrangement for an electronic ripple control receiver, which has an evaluation part for evaluating the received remote control signals, switching elements controllable by the evaluation part, and a switching energy store assigned to the switching elements for their actuation.

A ripple control receiver of this type is described in CH-PS 567 824. This ripple control receiver should be used in the ripple control receivers known until now LC resonant circuits or electromechanical resonance structures in the receiving part and the electromechanical switching mechanism in

Replace evaluation part with fully electronic circuits, especially with a single integrated circuit. As the only electromechanical switching element, this electronic ripple control receiver only has the switching element which can be actuated by the evaluation part, for example a surge switch.

The use of integrated circuits opened up the possibility of providing a control supply part of very low power; however, this was offset by the high energy requirement for actuating the impulse switch. This contradiction was solved in the known ripple control receiver by a switching energy store, for example a capacitor with high capacitance, which is kept in a charged state via a charging path from the power supply part of the ripple control receiver, so that it occurs when the switching element is actuated relatively rarely and at great intervals can briefly release the required switching energy.

The latter requirement - infrequent actuation of the switching element at a large interval - is still fulfilled, but there are ripple control receivers that are equipped with several switching elements that in certain cases receive the switching commands almost simultaneously. In order to be able to execute these switching commands, either the power of the power supply part or the capacity of the switching energy store would have to be increased accordingly. However, these two solutions are uneconomical and therefore not advantageous.

It is the object of the invention to provide a circuit arrangement for an electronic ripple control receiver, with the aid of which a plurality of switching elements can be safely switched using a power supply part of low power and a switching energy store with the lowest possible energy content.

According to the invention, this object is achieved by an arrangement for monitoring the energy content of the switching energy store, which, when the energy content falls below a first limit, delays the activation of the switching elements until a second, not less, limit value of the energy content is exceeded.

Through the proposed monitoring of the energy content of the switching energy storage device, the circuit arrangement according to the invention enables the safe actuation of a plurality of switching elements without the energy content of the switching energy storage device or the power of the power supply part having to be increased accordingly. The invention is based on the knowledge that it is not necessary to execute every switching command received instantaneously, but that time delays of a few milliseconds or even seconds can be tolerated, so that the activation of the switching elements is delayed for so long if the energy content of the switching energy store is insufficient can until it has sufficient energy content or, in other words, is recharged.

The invention is explained in more detail below on the basis of an exemplary embodiment shown in the drawing, the single figure showing a simplified circuit diagram of an electronic ripple control receiver with a switching element to be controlled remotely.

The ripple control receiver, designated 1 in the figure, is connected with its input terminals 2 and 3 to two conductors 4 and 5 of an AC network 6, to which remote control commands in the form of AC pulse sequences are superimposed in a known manner. Therefore, the input terminals 2 and 3 are connected to the AC line voltage Un as well as the signal voltage Us superimposed on this. The conductor 4 can for example be a phase conductor and the conductor 5 can be a neutral conductor.

To power the electronic ripple control tem5

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catcher 1, a power supply part 7 is provided, which has a series connection of a protective impedance 8, a series capacitor 9 and a full-wave rectifier 10 connected to the input terminals 2 and 3. The full-wave rectifier 10, designed as a Graetz rectifier, lies with its AC connections 11 and 12 in the series connection mentioned, while at the DC connections, i. a filter capacitor 15 and a voltage limiter 16, for example a Z-diode, are connected to the negative pole 13 and the positive pole 14. The protective impedance 8 can be, for example, a surge-proof resistor or a surge-proof choke coil.

The series capacitor 9 connected in series with the AC connections 11 and 12 of the full-wave rectifier 10 generates, based on the mains voltage Un, the voltage drop required for the operation of the electronic circuit of the ripple control receiver 1. Only a relatively low DC voltage of, for example, 20 V is required for this operation. The power consumption of the electronic circuit is very modest, so that the power supply part 7 has only a low output of, for example, about 0.3 watts.

From a switching point 17 between protective impedance 8 and series capacitor 9, a line 18 leads on the one hand to an input 19 of a frequency-selective receiving part 20 and on the other hand to an RC element 27 consisting of a resistor 28 and a capacitor 29. The receiving part 20, which for example has active RC Has filter as a selection means for the remote control frequency, is connected on the one hand to a minus busbar 21 and on the other hand to a plus busbar 22 and thereby receives the required supply voltage from the power supply part 7. An output terminal 23 of the receiving part 20 is connected via a line 24 to a first input 25 of the evaluation part 26 of the ripple control receiver 1. At a second input 32 of the evaluation part 26 there is a line 31 which branches off from a circuit point 30 between the resistor 28 and the capacitor 29.

A network-frequency signal is fed to the second input 32 of the evaluation part 26 via the RC element 27, with the aid of which a sequence of clock pulses bound to the mains frequency is formed in the evaluation part 26 for an electronic time base for the evaluation of the received pulse sequences.

The break frequency of the RC element is around 10 Hz, so that the network harmonics that are always present are damped relative to the network frequency.

The evaluation part 26, which is connected to the minus and positive busbars 21 and 22 and thus receives the required supply voltage from the power supply part 7, is implemented as a permanently programmed, preferably mask-programmed, one-chip microcomputer. Since electronic evaluation parts for ripple control receivers are known, further details can be dispensed with here. It should only be pointed out that the evaluation part 26 contains, among other things, electronic memories and shift registers for the temporary storage of received pulse sequences. Each such stored pulse sequence is compared with a pulse sequence assigned to the ripple control receiver in question (remote control command) and, if the comparison is positive, a first or second output 33 or 34 of the evaluation part 26 emits a good signal as an actuation signal for a switching element 35 to be remote-controlled 35. According to the illustration, the switching element 35 includes a switch 35 ', and depending on which of the two outputs 33 or 34 the good-finding signal appears, the switch 35' is switched on or off, as a result of which a power consumer 36 is connected to the network 6 or from this is switched off.

To actuate the switch 35 ', either a switching transistor 37 or 38 is turned on by the signal appearing at the output 33 or 34 of the evaluation part 26, so that one or the other of the two windings 39 and 40 of a relay 41 carries current and thereby the switch 35' switches on or off. Protective diodes 42 and 43 are connected in parallel with the windings 39 and 40 in order to protect the transistors 37 and 38 against inductive voltage surges.

Since the receiving part 20 and the evaluating part 26 of the ripple control receiver 1 have only a low power requirement of, for example, 0.2 watts, the power supply part 7 is also dimensioned for economic reasons only for the output of a relatively small power. For the actuation of the switching element 35, however, a larger power is temporarily required, which the scarce power supply part 7 could not deliver within a sufficiently short time. For this reason, the switching element 35 is assigned a switching energy store 44 in the form of a storage capacitor with a sufficient capacitance of, for example, 200 (iF).

The switching energy storage 44 is connected to the power supply part 7 via a charging path 45, which has a resistor 46. The resistor 46 can be relatively high-resistance and have a value of, for example, 400 ohms. The switching energy storage 44 is then charged relatively slowly from the power supply part 7, but is subsequently kept permanently in the charged state, so that it can deliver the energy required for a switching operation at any time. As long as the mains voltage Un is at terminals 2 and 3, the switching energy store 44 is charged and, because of the very low leakage current, retains its charge for a long time even if the mains voltage fails.

In the event of a temporary failure of the mains voltage, the supply voltage emitted by the power supply part 7 for the receiving part 20 and the evaluation part 26 drops and after a while will fall below the minimum voltage value for the correct functioning. It is then possible for undefined signals to be emitted at the outputs 33 and 34, which, in conjunction with the fact that the switching energy store 44 can still provide sufficient energy for the actuation of the switching element 35 for a long time, leads to an erroneous actuation of the switching element 35 and Switch 35 'can lead.

In order to avoid such undesirable switching processes, which are not triggered by remote control commands, the charging path 45 is assigned a discharging path 47 with a diode 48, the forward direction of which is directed to the power supply part 7. As soon as the supply voltage of the power supply part 7 drops by the starting voltage of the diode 48 below the voltage at the switching energy storage 44, the receiving part 20 and the evaluation part 26 are supplied with energy via the diode 47 from the switching energy storage 44 and the supply voltage of the receiving part 20 and evaluation part 26 drops together and uniformly with the voltage applied to the switching element 35. As soon as the drop falls below the minimum voltage value mentioned, an erroneous actuation of the switching element 35 could occur. However, this is prevented in that the response voltage of the switching element 35 is selected to be higher than this lower limit value for the supply voltage of the evaluation part 26. Because then, after falling below this limit value, the switching element 35 can no longer be actuated by mistake, because the switching energy store 44 is still located Voltage is too low to allow relay 41 to respond.

If only one switching element 35 with a switch 35 'is shown in the figure, then this should not be understood as restrictive, but the switching element 35 is intended to be representative

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can be seen for several switching elements. This is because ripple control receivers are able to receive switching commands for several switching elements 35 in quick succession.

It would now be obvious to dimension the switching energy store 44 in such a way that it can switch all connected switching elements 35 simultaneously or in quick succession without having to be charged in between. According to the invention, however, another, more cost-effective solution is proposed: this assumes that when switching commands are received for several switching elements 35, these switching commands do not have to be carried out immediately, but time delays of the order of a few seconds are problem-free and are therefore tolerated. The solution according to the invention consists in monitoring the voltage across the switching energy store 44 and, in the event of a voltage insufficient for the execution of a switching command, delaying the activation of the corresponding switching member or the corresponding switching members 35 until the switching energy store 44 is recharged.

According to the illustration, a line 51 with a Zener diode 52 and a resistor 53 is arranged parallel to the switching energy store 44, between its cathode 49 and anode 50. A line 54 branching off the positive busbar 22 leads to the emitter connection of a transistor 56, the collector connection of which is connected to the negative busbar 21 via a resistor 55 and the base of which is connected to the line 51 containing the Zener diode 52 via a resistor 57. The evaluation part 26 has a third input 58, to which a signal line 59 branching from the collector connection of the transistor 56 is connected.

The Zener diode 52 acts as a voltage reference for the switching energy storage 44. Because as long as the voltage across the

Switching energy store 44 is smaller than the Zener voltage of the Z diode 52, no current can flow from the plus bus 22 via the resistor 53 and the Z diode 52 to the cathode 49 of the switching energy store 44.

5 However, no emitter-base current can flow from the plus bus 22 via the line 54 into the transistor 56 and via the resistor 57 into the Z-diode 52 to the cathode 49 of the switching energy store 44. The switching transistor 56 thus blocks and the signal line 59 connected to it assumes the potential of the negative bus bar 21, since it is connected to it via the resistor 55.

In addition to the functions already described, the evaluation part 26 formed by a microcomputer can read the 15 input 58 and process it in its program. The microcomputer is programmed so that when the input 58 assumes the potential of the negative busbar 21, i.e. if the voltage across the switching energy store 44 is less than the Zener voltage of the Zener diode 52, any pending switching commands for the relay 41 are stored and are not executed. Only when the input assumes the potential of the positive busbar 22 does the evaluation part 26 execute the stored and / or the possibly newly arriving switching commands.

25 The input 58 only takes on the potential of the positive busbar 22 when the transistor 56 is on. However, this is only the case if a Zener current can flow through the Zener diode 52, that is to say the voltage across the switching energy store 44 is greater than the Zener voltage. An emitter-base current can then flow out of transistor 56 via resistor 57 and Zener diode 52, which turns on switching transistor 56.

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Claims (8)

666 771 1.Circuit arrangement for an electronic ripple control receiver, which has an evaluation part for evaluating the received remote control signals, switching elements controllable by the evaluation part, and a switching energy storage device assigned to the switching elements for their actuation, characterized by an arrangement for monitoring the energy content of the switching energy storage device (44), which at Falling below a first limit value of the energy content delays the activation of the switching elements until a second, not less limit value of the energy content is exceeded. 2. Circuit arrangement according to claim 1, characterized in that the two limit values of the energy content are the same size. 2nd PATENT CLAIMS 3. Circuit arrangement according to claim 2, characterized in that the arrangement for monitoring the energy content has a measuring circuit for measuring the voltage at the switching energy store (44) and an information store for temporarily storing the received remote control signals. 4. Circuit arrangement according to claim 3, characterized in that the evaluation part (26) is formed by a microcomputer and that the information memory is integrated therein. 5. Circuit arrangement according to claim 3 or 4, characterized in that the measuring circuit is a reference element (52) for the minimum energy required for actuating the switching elements (35) of the switching energy store (44) and a switching element (56) for emitting a signal has the evaluation part (26) when the voltage falls below the required minimum energy and is predetermined by the reference element. 6. Circuit arrangement according to claim 5, in which the switching energy store is formed by a capacitor, characterized in that the reference element (52) is formed by a Z-diode arranged in parallel with the capacitor (44). 7. Circuit arrangement according to claim 6, characterized in that the switching element (56) is formed by a transistor, the collector connection with the minus and the emitter connection with the Piussammeischiene (21 or 22) of the circuit arrangement and its base with which the Z- Diode (52) containing line (51) is connected. 8. Circuit arrangement according to claims 7 and 2, characterized in that a signal line (59) leads from the collector connection of the transistor (56) to an input (58) of the microcomputer forming the evaluation part (26), and that the microcomputer is programmed in such a way that that if the input mentioned assumes the potential of the negative busbar (21), it does not execute any switching commands for the switching elements (35), but stores them and only outputs them to the switching elements at this input when the potential of the positive busbar (22) is present.