DE2613929C3 - Circuit arrangement with a relay which has a normally open contact - Google Patents

Description

The invention relates to a circuit arrangement as described in the preamble of claim 1 specified type

Such a circuit arrangement which also suppresses the effects of the bouncing of the normally open contact is already known (DE-OS 23 60 564, Fig. 10). In the known circuit arrangement is parallel to Normally open contact of a relay is switched to a triac, the control signal of which is derived from the actuating current of the excitation coil of the relay is derived. For this purpose, a special control circuit is provided, with the help of which both a delay in the connection of the triac as well as its blocking is brought about. the Delay in switching on serves to reduce the current flow time in the triac. The delay has the purpose of compensating for the relay's fall time. the known control circuit requires a certain additional effort, also is to achieve the required delay in disabling the triac, a certain dimensioning of the control circuit is required, which also takes into account the influence of the no-load diode provided in the relay got to.

From the magazine "Der Elektromeister Deutsches E! Ektrohandwerk / de". Vol. 48, 19-3, issue 8, pages 571 and 572, the galvanic decoupling of circuits by the optoelectronic coupler is known.

The object of the invention is to provide a circuit arrangement of the type mentioned at the beginning the input and output circuits are galvanically isolated from each other and in the case of the circuitry Effort to achieve the necessary delay in disabling electronic switching is reduced.

According to the invention, the circuit arrangement for solving the problem in the im characterizing part of claim 1 specified manner formed.

The energy stored in the excitation coil flows away via the light-emitting diode and the limiter diode and keeps the optocoupler and the electronic switch until after the final shutdown of the Working contact conductive, without a special delay network is required for this.

Such types are used as optocouplers in which the switching state of the controlled Element in every moment of the current in the Light-emitting diode depends, for example, optocouplers of the type light-emitting diode / phototrensist, light-emitting diode / photodiode.

Should with. With the help of the relay direct currents are switched are, the circuit arrangement is expediently designed such that the electronic

Switch one with its emitter-collector path parallel to the normally open contact of the relay and with its base connected to the output of the optocoupler transistor is The normally open contact is introduced into the direct current path in such a way that the emitter-collector path located parallel to the normally open contact of the transistor is in the direct current path with the polarity customary for the type of transistor used.

If alternating current is to be switched with the aid of the relay, the circuit arrangement can be shown in Development of the invention advantageously train such that the electronic switch by two, with transistors connected in series to their emitter-collector paths with opposite polarity is formed such that the series circuit is parallel to Working contact of the relay is arranged, and that both transistors are parallel to the emitter-collector path such a polarized diode is arranged that hot an npn transistor, the emitter with the The anode and, in the case of a pnp transistor, the emitter is connected to the cathode the circuit arrangement is also recommended for those applications in which any polarity of a to be switched direct current should be possible. On the other hand, in a further embodiment of the Invention train the circuit arrangement such that the electronic switch by two, with their Emitter-collector paths are formed in antiparallel-connected transistors, and that the emitter-collector path in each case one such polarized Diocie is connected in series that it has an inverse operation of the associated transistor prevented.

Further advantageous configurations of the invention emerge from the subclaims 6 to 12.

Embodiments of the invention are based on FIGS. 1 to 3 explained. It shows

F i g. 1 shows a circuit arrangement for suppressing bouncing in the case of a normally open contact of a relay which is provided for switching direct current of predetermined polarity, w

F i g. 2 shows a circuit arrangement for suppressing bouncing with an additional switch-on delay circuit and

F i g. 3 shows a circuit arrangement for suppressing bouncing in the case of a -ti normally open contact of a relay intended for alternating current.

The circuit arrangement shown in Fig. 1 contains a relay which has an excitation coil A and a normally open contact a. The relay is inserted into an adapter in such a way that the ίο working contact a is directly connected to the connections 3 'and 4' and the winding A is directly connected to the connections Γ and 2 '. The adapter also has ports 1 ... 4, of which port 3 is directly connected to port 3 ', port 4 is directly connected to port 4' and port 2 is directly connected to port 2 '. The light-emitting diode 71, which is part of the optocoupler 7, is located between the connections 1 and Γ. The anode of the light-emitting diode 71 is connected to the connection Γ mi and the cathode to the connection 1.

The emitter-collector path lies parallel to the normally open contact a of the transistor 51. The emitter of the transistor 51 is connected to the terminal 3 ' And connected to its collector with the 4 'terminal. Between connections 1 or »-« and 2 or "+" is the diode 61, the anode of which is connected to the cathode of the light-emitting diode 71, so that the Light emitting diode 71 and diode 61 are connected in series with the same polarity.

From the transistor 72 contained in the optocoupler 7 is the emitter with the base of the transistor 51 and the collector with the collector of the transistor 51 tied together.

In the case of the in FIG. 1 shown debounce circuit for the Relay contact a of the relay, an electronic switch is connected in parallel to mechanical contact a. The electronic switch, formed by the transistor 51 controllable by means of the optocoupler 7, takes over the contact current while being hooked in and unhooked, overlapping with contact a.

Since the transistor 51 switches on faster than the contact a and - due to the process described in the following paragraph - switches off with a longer delay than the contact a, all contact bruises are bridged.Due to the collector-emitter threshold voltage flows when switched on or after the bouncing has ended the entire current through the contact a, so that the transistor 51 is not thermally stressed. The Optokoppi> r 7 ensures the galvanic separation of the relay between the input circuit with the excitation coil A and the output circuit with the working ammonia a.

The hot coil A also serves as a series resistor for the light-emitting diode 71 and thereby causes a current limitation. The freewheeling or quenching diode 61 is not, as is known, directly on the excitation coil A, but in series. Light-emitting diode 71, the series circuit of the two diodes is located on the relay coil A 61 and 71 is thereby achieved is that when switching off of the guided to the excitation coil A DC control voltage stored in the exciting coil A energy in the form of a decaying current through the light emitting diode 71 and the extinguishing diode 61 flows off and thereby keeps the transistor 51 conductive via the optocoupler 7 until after the contact a is finally switched off.

The circuit arrangement according to FIG. 2 contains like that in FIG. 1 arrangement shown an adapter with a relay and its contact a. In addition, in the debounce circuit according to Fi g. 2 a switch-on delay circuit arranged in the control circuit. The switch-on delay circuit consists of the resistor 9, the capacitor 8, the Zener diode 62 and the transistor 52. The emitter-collector path of the transistor 52 is arranged in the control circuit and its emitter is connected to terminal 1 of the control input and its collector the connection point of the diodes 61 and 71, and led with its base via the Zener diode 62 to the connection point of the capacitor 8 and the resistor 9. The transmission circuit consisting of the capacitor 8 and the resistor 9 is connected to the control input 1,2.

Furthermore, in FIG. 2 the transistor 5t as a transistor in Darlington circuit formed with integrated emitter resistors. The current gain is the The transistor 51 is dimensioned in such a way that the transistor 51 takes into account the contribution of the limiting addition 61 in the extension of the period of time during which the cut-off current flows compared to the Normally open contact a switches on faster and switches off with a longer delay.

Furthermore, a Zener diode 63 is connected in parallel to the normally open contact a, which with its anode on Emitter of transistor 51 is located. The polarity of the zener diode is such that it is overfed when one is switched off

si »is

Working contact a switched inductance due to the greater induced voltage compared to the Zener voltage Voltage becomes conductive;

When applying voltage to the terminals 1 and 2, the capacitor 8 must first via the resistor 9 be charged to the extent that the Zener diode 62 and thus the transistor 52 becomes conductive.

In the circuit arrangement according to Figi3 is the electronic switch by the two, with their emitter-collector paths opposite to each other Polarity of series-connected transistors 53 and 54 are formed. The series connection of the two emitter-collector lines is parallel to contact a of the relay. In addition, both transistors 53 and 54 A diode 531 or 54 i is arranged parallel to the Emitler collector path.

The transistors 53 and 54 are each Darlington transistors. The integrated circuit executed Transisiursysienie eninauefi two each transistors connected to one another on the collector side, each of which has a resistor between the emitter and base. The emitter of an input side The transistor is connected to the base of a transistor on the output side. Parallel to the emitter-collector path of the transistor arranged at the output, there is a diode 531 or 541, respectively. The transistors 53 and 54 are npn transistors. Therefore, the emitter of transistor 53 with the anode of diode 531 is the emitter of transistor 54 is connected to the anode of diode 541.

Each of the two transistors 53 and 54 is controlled by its own optocoupler. The light-emitting diodes contained in the two optocouplers 74 and 75 are connected in series, the series connection of the two light-emitting diodes 72 and 73 in turn being in series with the excitation coil A of the relay.

The two optocouplers 74 and 75 are on the output side with the collectors of the contained in them Transistors merged. Furthermore, the collector connections of the optocouplers 74 and 75 are on the one hand and those of transistors 53 and 54 are merged, like this that the collectors of the four transistors are directly connected to one another. Furthermore is the emitter of the transistor contained in the optocoupler 74 with the base of the transistor 53 and the emitter of the irfi Optocoupler 75 contained transistor with the base of transistor 54 connected.

In the circuits of FIGS. 1 and 2 must be correct polarity of the contact connections must be observed

the. In the circuit arrangement according to F i g; 3 needs not paying attention to the polarity. This contact is particularly useful for switching Suitable for alternating current. The mode of operation largely corresponds to the circuit arrangement of FIG. 1, where however, a separate Darlington transistor 53 or 54 and optocoupler 74 or 75 for each current direction are provided. The integrated diode 531 or 541 of each Darlington transistor 53 or 54 is bridged üiesei'i each time for the wrong message.

In the exemplary embodiments shown in the figures, the circuit arrangement is in an adapter housed, which is inserted between a relay socket and the associated relay. Such Arrangement has the advantage that it can be used retrospectively, for example when the Operation of a relay circuit turns out that chatter shocks of the relay must be eliminated.

On the other hand, the circuit arrangement can advantageously be accommodated in the relay socket from the outset or structurally combine with the relay.

In the case of optocouplers, where the base connection is brought out from the phototransistors, one can expediently put the base through a high resistance resistor to the emitter and this way Eliminate any disturbing residual currents of the phototransistor.

The phototransistors contained in the optocouplers 7, 74 and 75 are npn transistors. When using of pnp phototransistors, the emitter and collector are to be interchanged

Claims (11)

Patent claims: 1. Circuit arrangement with a DC-fed relay, in which a diode is provided to limit the cut-off voltage emanating from the excitation coil of the relay, in which a controllable electronic switch that takes over the current in the normally open contact circuit during the switching operations is also connected in parallel to the normally open contact of the relay, for the the control signal of the relay is derived from tu the operating current of the exciting coil, characterized in that seen for the control of the electronic switch at least one opposed to the light emitting diode (71) in the exciter coil circuit optocoupler (7) upstream \ * and in that the limiter (61 ) is polarized parallel to the series connection of light emitting diode (71) and excitation coil (A) in such a way that the excitation coil (A) can send current via the series connection of light emitting diode (71) and limiter diode (61) as soon as it is switched off (Fig. 1) . 2. Circuit arrangement according to claim 1, characterized in that the electronic switch is a transistor (si) connected with its emitter-collector path parallel to the normally open contact (a) of the relay and with its base connected to the output of the optocoupler (7) ( Fig. 1,2). 3. Circuit arrangement according to claim 1, characterized in that the electronic switch is formed by two transistors (53, 54) connected in series with their emitter-collector paths «1 with opposite polarity, such that the series circuit par, 'IeI to the normally open contact (a) of the relay is arranged, and that in both transistors (53, 54) each p / parallel to the emitter Js collector path a polarized diode is arranged that in an npn transistor the emitter with the Anode and, in the case of a pnp transistor, the emitter is connected to the cathode (FIG. 3). 4. Circuit arrangement according to claim 1, characterized in that Ί " characterized in that the electronic switch by two, with their emitter-collector paths anti-parallel connected transistors is formed, uiid that the emitter-collector path is connected in series with a polarized diode in such a way that it Ί5 prevents inverse operation of the associated transistor. 5. Circuit arrangement according to one of claims 2 to 4, characterized in that the transistor (51, 53, 54) is in each case a transistor in ^r ><> Darlington circuit (F i g. 2, 3). 6. Circuit arrangement according to claim 2, characterized in that a Zener diode (63) is connected in parallel to / around normally open contact (a). 7. Circuit arrangement according to one of the previous "> ί pending claims, characterized in that a delay circuit (8,9,62,52) in the control circuit is arranged (Fig. 2). 8. Circuit arrangement according to claim 7, characterized in that the delay circuit contains a transistor (52) which, with its Erriilter ^ KöIlektor path in the steeper circle angeord ^ net is, with its emitter to a connection (1) of the control input and with its base via a Zener diode (62) led to the connection point of a capacitor (8) and a resistor (9) is, and that the series connection of the capacitor (8) and the resistor (9) at the control input (1, 2) lies (Fig, 2), 9. Circuit arrangement according to one of the preceding claims, characterized by the Arrangement in a relay sock, 10. Circuit arrangement according to one of claims 1 to 8, characterized by the structural Association with the relay. 11. Circuit arrangement according to one of claims 1 to 8, marked by the ano, dnung in an adapter that can be used between the relay socket and the relay.