DE3905921A1 - Remote-control circuit for a DC load - Google Patents

Abstract

The invention relates to a remote-control circuit for a load (V) having control input (4), such as a multi-ring chime, which is connected to an AC source via a rectifier/filter circuit or a rectifier circuit, one control signal triggering one specific effect, for example the operation of a chime. A problem consists in that transmission of the control signal has hitherto required, in addition to the two strands of the power supply, at least a third line or an expensive RF transmission. A third line is associated with increased expenditure, and in particular, only two lines are often available, for example when subsequently installing more modern chime devices in old buildings, where there has so far been only a two-core bell line available. The solution of the problem consists in providing a short-circuiting switch (S) for the rectifier circuit (D1), and a storage medium which is charged up when the short-circuiting switch (S) is open and is discharged when the short-circuiting switch (S) is closed, the charge delivering a control signal to the control input (4) of the load (V) via a control circuit (1). <IMAGE>

Description

The invention relates to a remote control circuit according to the preamble of claim 1.

In particular, the invention relates to a remote control circuit for a gong with AC power supply, the regardless of the duration of the control signal with a tone sequence given duration.

So far, for a power supply of such a consumer two wires necessary. For driving the consumer to trigger any effect, for example a gong in the To operate the apartment is at least one additional wire required when using the 0 wire of the power supply used. This is with a corresponding additional effort on wires connected, but in particular it makes driving one Consumers impossible if there is no additional third wire can be retrofitted. This is for example at Old buildings are the case where previously only a two-core Bell line was provided as a simple doorbell permanent power supply needed.

In the case of similar problems (e.g. toy trains etc.) is generated by superimposing an RF control signal on the supply voltage, relatively expensive Control signal generated.

There is therefore the problem to a consumer of the beginning mentioned type, which requires its own power supply, only over the two wires of this power supply without Generation of an RF frequency also to transmit a control signal.

The problem is compounded by the characteristics of the Claim 1 solved. Further configurations of problem solving are listed in the subclaims.  

The basic principle is to provide a control circuit on Consumer at standby during DC operation of the consumer through the positive half wave of connected rectified alternating current a storage medium is charged when the rectifier circuit is bypassed with the help of the now supplied to the control circuit Alternating current is discharged and the charged current in Form of a control signal to the consumer.

A capacitor is preferably provided as the storage medium, a transistor can be used to deliver the control signal that is initially blocked, only when one is fed Alternating current to the control circuit and then delivers the control signal to the consumer via the collector. Instead of the transistor, a relay can also be used due to the negative tax half-wave after closing the Bridging switch switches and a connection of the storage medium with the control input of the consumer, with the discharge of the storage medium, the stored current is supplied as a control signal.

With a convenient simple structure of the control circuit a first rectifier diode is provided at the input, the Output with the positive connection of the storage capacitor, a second resistor, an interference suppression capacitor and the Emitter terminal of a transistor is connected during the negative connection of the storage capacitor connected to ground is and the second terminals of the second resistor and Interference suppression capacitor connected to the base of the transistor are. The collector of the transistor is connected to the control input connected to the consumer. The first resistance is Base still connected to the input of the rectifier diode.  

The consumer can like via a further rectifier circuit a diode across the output of the first input rectifier circuit be powered; but he can also via a second rectifier circuit like a second diode inside the control circuit, which is in front of the storage medium anyway must be provided to be supplied with electricity. In in this case, you save a somewhat longer connection line to the consumer and in particular another rectifier circuit, as well as a necessary filter capacitor.

The storage medium is preferably a storage capacitor however, an accumulator can also be used. The preferred application is a multi-tone gong or continuous tone gong with AC power supply. The first input rectifier circuit can then be at an entrance, for example the bell button corresponds to the bypass switch at which This makes the activity in the house or apartment located gong operated. Such a gong can be independent from the duration of the control signal a tone sequence with a predetermined Submit duration.

Embodiments of the invention are in the drawing shown. It shows

Fig. 1 shows a first embodiment of a remote-control circuit with a transistor drive circuit and a power supply to the load via a further rectifier circuit,

The drive circuit FIG. 2 is substantially represented in Fig. 1, but wherein the power supply to the load is carried directly over an existing second rectifier circuit from the storage medium,

, Fig. 3 is a remote control circuit being provided as a drive circuit, a relay circuit and the power supply of consumers is carried out immediately via an existing anyway second rectifier circuit,

Fig. 4 essentially the embodiment shown in Fig. 3, but the power supply to the consumer is carried out via a further rectifier circuit.

A first embodiment of the invention is shown in FIG. 1. An AC transformer with a low output voltage U _sec , generally 12 V, is shown on the left side of FIG. 1. This output is followed by a rectifier circuit (D 1 ) which is bridged by a bypass switch (S) . The memory circuit ( 1 ) is arranged within the dashed rectangle. The output terminal of the rectifier circuit (D 1) is denoted by (3), referred to the input terminal of the control circuit (1) with (2). The phase line leads from the connection ( 2 ) to the consumer (V) , while the second - 0 connection (N) is shown in the lower region of FIG. 1.

The connecting terminal ( 2 ) simultaneously forms the input for a second rectifier diode (D 2 ) within the control circuit ( 1 ), while the output of the rectifier diode (D 2 ) is the one with the positive connection of a storage capacitor (C 1 ) and an interference suppression capacitor (C 2 ) and a first terminal of a (second) resistor (R 2 ) and the emitter terminal (E) of the transistor (Tr) is connected. The negative connection of the storage capacitor (C 1 ) is connected to the terminal ( 5 ) with the 0 line (N) , the second connections of the second resistor (R 2 ) and the interference suppression capacitor (C 2 ) are connected to the Base (B) of the transistor (Tr) connected. The terminal ( 2 ) is also connected to the base (B) of the transistor (Tr) via a first series resistor (R 1 ). The rectifier diode (D 2 ) causes the presence of a DC voltage regardless of the voltage conditions at the connection ( 2 ). In the state shown in FIG. 1 with the bypass switch (S) open, the storage capacitor (C 1 ) is charged and the transistor (Tr) is blocked. If the switch (S) is closed, AC voltage arrives at the connection ( 2 ), which is fed through the series resistor (R 1 ) to the base (B) of the transistor (Tr) and makes the transistor (Tr) conductive. The charge stored in the storage capacitor (C 1 ) is delivered in the form of a voltage pulse to the control input ( 4 ) via the collector connection (C) . This voltage pulse initially rises fairly quickly and then falls relatively quickly and then more slowly. The discharge takes place from the control input ( 4 ) of the consumer to the 0 line (N) . The provided interference suppression capacitor (C 2 ) works together with the second resistor (R 2 ) only as interference suppression of the circuit, the capacitor (C 2 ) itself is only charged when the negative half wave is applied.

The power supply to the consumer (V) takes place via a line which is connected to the input connection ( 2 ), with a further rectifier circuit in the form of a third rectifier circuit (D 3 ). A filter capacitor (C 3 ) is connected in parallel to the consumer (V) , the positive connection of which is connected to the output of the rectifier diode (D 3 ).

Thus, the first positive half-wave of the initially rectified AC power source is not only used for the standby power supply of the consumer, but at the same time for charging a storage capacitor within a control circuit. Closing the bridging switch (S) leads AC voltage both to the consumer suitable for this purpose and to the base of a switching transistor (Tr) , which thereby becomes conductive, discharges the storage capacitor and supplies a control voltage to the consumer. This eliminates the need for a third wire.

In the exemplary embodiment of FIG. 2, the same parts are provided with the same reference symbols. The only difference compared to the embodiment of Fig. 1 is that a supply line from the input terminal ( 2 ) via the third rectifier diode (D 3 ) to the consumer (V) is missing, as is the filter capacitor (C ) connected in parallel to the consumer (V) 3 ). Instead, the output line of the second rectifier diode (D 2 ) is simply connected to the consumer input. The rectifier diode (D 2 ) thus also causes rectification for the consumer (V) . Likewise, the storage capacitor (C 1 ), which is present anyway, also acts as a filter capacitor for the consumer (V) . This circuit thus represents a simplification compared to the embodiment of FIG. 1.

Fig. 3 differs from the embodiment of Fig. 2 essentially in that the transistor drive circuit consisting of transistor (Tr) with base (B) , emitter (E) and collector (C) , interference suppression capacitor (C 2 ) and two Resistors (R 1 , R 2 ) is replaced by a relay circuit which is clamped between the supply line in front of the second rectifier diode (D 2 ) and essentially consists of a relay (RS) , which is a fourth from the neutral conductor (N) Rectifier diode (D 4 ) is connected upstream. A holding capacitor (C 4 ) is connected in parallel to the relay (RS) . The relay has a switching contact which, when actuated, connects the positive output of the storage medium, in particular the capacitor (C 1 ), to the control connection ( 4 ) of the consumer (V) .

The holding capacitor (C 4 ) is charged via the rectifier (D 4 ) during the negative half-wave, ie when the bypass switch (S) is bridged, and the relay is held via the holding capacitor (C 4 ) for the duration of the positive half-wave. When the bypass switch (S) is bridged, the relay contact between the positive connection of the storage capacitor (C 1 ) and the control input ( 4 ) of the consumer (V) is closed.

Fig. 4 shows essentially the embodiment of Fig. 3, but from the input ( 2 ) of the control circuit ( 1 ) has its own consumer connection via a further third rectifier diode (D 3 ) supplies the consumer (V) with current. Furthermore, a filter capacitor (C 3 ) is connected in parallel to the consumer (V) . In this regard, FIG. 4 corresponds to the exemplary embodiment of FIG. 1, while the control itself takes place in exactly the same way as in the exemplary embodiment of FIG. 3.

Claims (11)

1. Remote-control circuit for a DC load (V) with control input (4) connected via a rectifier-filter circuit or a rectifying circuit is connected to an alternating current source, characterized by

• a) a bypass switch (S) for a first rectifier circuit (D 1 ),
• b) a control circuit ( 1 ) on the consumer (V) , the input ( 2 ) of which is connected to the consumer output ( 3 ) of the rectifier circuit (D 1 ), and the output of which is connected to the control input ( 4 ) of the consumer (V ) is connected
• c) a storage medium (C 1 ) connected in parallel with the AC power supply, which is charged when the bypass switch (S) is open by a half-wave (storage half-wave) of the rectified current, the control circuit when the bypass switch is closed using the other half-wave (control half-wave) of the current one Alternating current delivers a control signal to the control input ( 4 ) of the consumer (V) and the storage medium (C 1 ) is discharged.

2. Circuit according to claim 1, characterized in that a second rectifier circuit (D 2 ) is provided at the input of the control circuit ( 1 ), the output of which with the storage medium (C 1 ) and the emitter (E) of a transistor (Tr) , and whose input is connected via a first resistor (R 1 ) to the base (B) of the transistor, and that the collector (C) of the transistor is connected to the control input ( 4 ) of the consumer (V) , such that an input AC voltage after closing the bridging switch (S) makes the transistor (Tr) conductive and supplies the charge stored in the storage medium (C 1 ) via the emitter-collector connection in the form of a drive pulse to the drive input ( 4 ). 3. A circuit according to claim 2, characterized by the parallel connection of a second resistor (R 2 ) and an interference suppression capacitor (C 2 ) between the output of the second rectifier circuit (D 2 ) and the base input (B) of the transistor (Tr) , and the connection of the positive connection of the storage medium (C 1 ) to the output of the second rectifier circuit (D 2 ) and the ground connection of the negative connection of the storage medium (C 1 ). 4. A circuit according to claim 1, characterized in that the switching element of the control circuit is a parallel to the AC power supply relay (RS) , which preferably has a capacitor (C 4 ) connected in parallel, and which bypassing the bypass switch (S) via a fourth Rectifier circuit (D 4 ), which is connected in reverse to the first rectifier circuit (D 1 ) and is arranged on the neutral side of the relay (RS) , the second half-wave is supplied in the form of the control half-wave, the relay output being between a second rectifier circuit (D 2 ) and the control input ( 4 ) of the consumer (V) arranged bridges and thus enables the supply of the current stored in the first storage medium (C 1 ) to the control input ( 4 ). 5. Circuit according to one of claims 1 to 4, characterized in that the output of the second rectifier circuit (D 2 ) both with the positive connection of the storage medium (C 1 ) for obtaining the control signal at the control input ( 4 ) of the consumer (V) as is also connected to the consumer input for the supply of permanent direct current ( Fig. 2, Fig. 3). 6. Circuit according to one of claims 1 to 5, characterized in that the storage medium (C 1 ) is a storage capacitor. 7. Circuit according to one of claims 1 to 5, characterized characterized in that the storage medium is an accumulator.   8. Circuit according to one of claims 1 to 4 or 6 to 8, characterized in that the input of the control circuit via a third rectifier circuit (D 3 ) is connected to the consumer input, preferably a filter capacitor (C 3 ) parallel to the consumer (V ) is switched. ( Fig. 1, Fig. 4). 9. Circuit according to one of claims 1 to 8, characterized in that the consumer (V) is a multi-tone gong or a continuous tone gong with AC power supply, which can be actuated by closing the bridging switch (S) . 10. Circuit according to one of claims 1-9, characterized in that the control circuit ( 1 ) and the consumer (V) form a spatial unit. 11. Circuit according to one of claims 1-9, characterized in that the control circuit ( 1 ) and consumer (V) form spatially separate units.