DE4116947C2 - Coupling relay circuit - Google Patents

Description

The present invention relates to a Coupling relay circuit, in particular Hybrid power relay circuit according to the preamble of Claim 1.

Such relay circuits are, for example, in programmable logic controllers used in which they for the implementation of control signals in power supply and -shutdowns serve. The switched Power spikes avoided and a sufficient spark suppression can be achieved when switching off.  

In a known hybrid power relay circuit trained coupling relay circuit is parallel to Working contact pair in addition to the varistor, the series connection from capacitor and current limiting resistor, to which the latter a diode is connected in parallel. This gives effective spark suppression when the load is switched off or Opening the pair of normally open contacts, as when opening the switch the capacitor, which is in the closed state of the Switch over the current limiting resistor completely has discharged through the load to be switched off flowing current charges, which is because of the continuing flow Load current at the opening contact pair current voltage drop can be lower. Shutdown voltage peaks take effect through the varistor limited.

A disadvantage of this known coupling relay circuit however, that it is polarity bound, so only when switching of direct currents is effective.

The object of the present invention is a Coupling relay circuit, in particular Hybrid power relay circuit of the type mentioned at the beginning create with the correspondingly effective spark extinguishing and cut-off voltage peak limitation also alternating currents (without a residual current caused by the extinguishing circuit) can be switched.  

To solve this problem are in a coupling relay circuit of the type mentioned the features specified in claim 1 intended.

The measures according to the invention are highly effective Spark suppression achieved, which is not polarity-bound and therefore both when switching direct currents as well as from AC currents is effective. Because of the diodes for both the positive as well as for the negative half wave one AC flow paths across the charging capacitor can also result in the pair of work contacts when opening be bridged with low resistance, so that the load current initially can continue to flow through the condenser, what about the Working contact pair only an insignificant voltage drop creates. The voltage at the make contact pair increases flattened during opening and a voltage limit sets in through the varistor, so that the Shutdown voltage peak is effectively limited. The Auxiliary contact pair is protected in the same way.

The features according to claim 2 are expedient intended. Are also the features according to claim 3 provided, it is ensured that in the closed State of the two switch parts of the capacitor over the Current limiting resistor can discharge.  

With the features of claim 4 is achieved that a Bouncing of the two contact pairs without affecting the Effectiveness of spark suppression remains and that the switching work is distributed to both contact pairs.

According to a further embodiment, as described by the Features is provided according to claim 5, is achieved in that the circuit can be simplified as far as Capacitor does not have the parallel connection of diode and Current limiting resistor but directly to the concerned of the aforementioned diodes can be connected. The advantage this circuit is that the quenching circuit is something is lower resistance and that so far the Current limiting resistor parallel diode can be omitted.

In a further embodiment of the present invention the features are provided according to claim 6. Thereby creates a circuit that is the first pair of make contacts by the one controlled via the second pair of make contacts Relief field effect transistor. The switching work for the EIN and OFF is taken over by the field effect transistor and the first pair of make contacts almost only carries the continuous current.

With the features according to claim 7 is achieved by that Zener diode the control voltage of the field effect transistor is limited.  

The features according to claim 8 are expedient intended.

According to a further exemplary embodiment Invention, the features according to claim 9 are provided. This achieves a circuit which, due to the shorter switching time of the first field effect transistor, such as the double load current like a circuit after just one Field effect transistor having the aforementioned Embodiment can switch.

With the features according to claim 10 it is achieved that in one of the two operating states of the circuit the output side Voltage at the second field effect transistor from the control circuit of the first power field effect transistor can be separated.

With the features of claim 11 is achieved by the zener diode the control voltage of the first Power field effect transistor is limited.

With the features according to claim 12 is achieved that normal adjusted relays can be used because the The normally closed contact pair always opens before the normally open contact pair closes, and only closes after the pair of normally open contacts has opened again. A special adjustment of the relay is not necessary Consequently.  

Further expedient configurations result from the Features according to claim 13.

Further details of the invention are as follows Description can be found in the invention under Reference to a known circuit using the in the Described embodiments described and drawing is explained.

Show it:

Fig. 1 is a Hybrid power relay circuit for switching DC currents according to the prior art,

Fig. 2 is a Hybrid power relay circuit according to a first embodiment of the present invention,

Fig. 3 is a hybrid power relay circuit according to a variant of the first embodiment according to Fig. 2,

Fig. 4 shows a hybrid power relay circuit according to a second embodiment of the present invention and

Fig. 5 is a Hybrid power relay circuit according to a variant of the second embodiment according to Fig. 4.

First, a known coupling relay circuit in the form of a hybrid power relay circuit 1 according to the prior art will be briefly described with reference to FIG. 1. The circuit 1 has a relay 2 with excitation coil connections 3 and a pair of normally open contacts 4 , which can be bridged by a switching element 5 movable by the relay 2 . Parallel to the pair of normally open contacts 4 is a series circuit comprising a current limiting resistor 6 and a charging capacitor 7 and also a varistor (voltage-dependent resistor) 8 in parallel with this. Parallel to the current limiting resistor 6 is a diode 9 , which is arranged in accordance with the DC voltage source 10 in the forward direction from its positive to its negative pole. With this polarity-bound hybrid power relay circuit 1 , which is only effective for switching direct currents, a load 11 of any type can be switched without radio interference.

With the coupling relay circuit 12 or 12 'and 22 or 22 ' shown as a hybrid power relay circuit in the drawing according to several exemplary embodiments or variants, the load 11 in question can be switched on and off not only under DC voltage conditions but also under AC voltage conditions. Here, too, a highly effective spark extinguishing and a cut-off voltage peak limitation are effectively achieved.

Referring to FIG. 2 12 18 having the hybrid power relay circuit, a relay d1 with exciting coil terminals 14, a first and second normally open contact pair 15, 16, and switching elements 17, with which the respective working contact pair 15 and 16 can be bridged with energization of the relay d1 . In this exemplary embodiment, the two pairs of normally open contacts 15 and 16 , of which the second pair of normally open contacts 16 is an auxiliary contact pair, open and close simultaneously. In the course of the first pair of normally open contacts 15 , the load 11 and an AC voltage source 19 are located for supplying the load 11 .

Parallel to the second pair of normally open contacts 16 are both the series circuit comprising a current limiting resistor r2 and a charging capacitor k1 and a varistor (voltage-dependent resistor) r1. A diode n1 is connected in parallel to the current limiting resistor r2, its cathode being connected to the connection between the voltage limiting resistor r2 and the capacitor k1. The respectively corresponding or adjacent normally open contacts of the two normally open contact pairs 15 , 16 are connected by means of a diode n5 or n2, the cathode of the diode n5 being connected to the relevant contact of the second normally closed contact pair 16 and the cathode of the diode n2 being connected to the relevant contact of the first normally open contact pair 15 is connected. In addition, a diode n4 and n3 is connected between the respective opposite working contacts of the two working contact pairs 15 and 16 , the cathode of the diode n3 with the cathode of the diode n5 and thus with the one working contact of the second working contact pair 16 and the anode of the diode n4 with the Anode of the diode n2 and thus connected to the other normally open contact of the second pair of normally open contacts 16 .

The function of this circuit 12 is as follows: by a positive half-wave of the supply voltage of the AC voltage source 19 , the capacitor k1 is charged via the current path from the diode n5, the diode n1, the capacitor k1 and the diode n2, while in the case of a negative half-wave via the Current path with the diode n3, the diode n1, the capacitor k1 and the diode n4 takes place, when, as shown in FIG. 2, the relay d1 is de-energized and both pairs of make contacts 15 , 16 are open. The varistor r1 serves to protect the circuit 12 against overvoltages.

If the relay d1 is energized, both pairs of make contacts 15 , 16 are bridged or closed via the respective switching element 17 , 18 . The normally open contact pair 15 switches the load circuit in terms of AC voltage (or DC voltage), while the second normally open contact pair enables the capacitor k1 to discharge via the current limiting resistor r2.

If relay d1 is then de-energized, both pairs of make contacts 15 , 16 are opened. However, the first make contact pair 15 remains at the moment of its opening by the series connection of the diodes n5 and n1, the uncharged capacitor k1 and the diode n2 or, in the case of AC voltage, by the series connection of the diodes n3 and n1, the uncharged capacitor k1 and the diode n4 bridged with low resistance so that the load current can continue to flow. Only an insignificant voltage drop occurs at the opening first pair of normally open contacts 15 , as a result of which the formation of a switching spark is suppressed. In the further course of time, the capacitor k1 is charged and the voltage at the first pair of normally open contacts 15 increases flattened. It then uses the voltage limitation through the varistor r1, so that the switch-off voltage peak is also effectively limited. The second pair of normally open contacts 16 is protected in the same way.

If the relay d1 is energized again, its two pairs of normally open contacts 15 and 16 close and the process described above takes place again.

If the relay d1 is adjusted so that its second contact pair 16 closes before its first contact pair 15 and opens after this, the contact pair 16 takes over the connection and disconnection work and the contact pair 15 takes over the management of the continuous current. This largely avoids switching sparks caused by contact bouncing.

In the variant of a hybrid power relay circuit 12 'shown in FIG. 3, which uses a corresponding relay d2 with two pairs of normally open contacts 15 ' and 16 ', the capacitor k1 is not, as in FIG. 2 via the parallel connection of the diode n1 and the Current limiting resistor r2 but directly connected to the connection point of the two diodes n3 and n5. The second make contact pair 16 'is in series with the current limiting or discharge resistor r2 and together with this in parallel to the capacitor k1. The further circuit arrangement with regard to the diodes n2 to n5 corresponds to the arrangement according to FIG. 2. The diode n1 is omitted in the circuit 12 'according to FIG. 3 and the so-called quenching circuit in parallel with the two pairs of normally open contacts 15 ' and 16 'is somewhat lower than in the embodiment of Fig. 2. in this circuit 12 ', but it must be ensured that the second normally open contact pair 16' 'includes and before the first normally open contact pair 15' after the first normally open contact pair 15 opens, as r2, and the second else in light contact bounce of the current limiting resistor Working contact pair 16 'would also have to temporarily take over the load current and would heat up inadmissibly. The mode of operation of this circuit 12 'is otherwise the same as that of the circuit 12 according to FIG. 2.

In the hybrid power relay circuit 22 of FIG. 4 is also a relay d2 is used, wherein said second normally open contact pair 16 'closes before the first normally open contact pair 15' and opens after this first normally open contact pair 15 ', which can be effected by a Spezialjustage the relay d2 .

In this exemplary embodiment, the first make contact pair 15 ′ is in the course of the AC voltage source 19 and the load 11 .

Compared to the circuit 12 according to FIG. 2, the circuit 22 is expanded by a MOS field-effect transistor T1, a zener diode n6 and two resistors r3 and r4. This creates a circuit arrangement which relieves the first normally open contact pair 15 'by the MOS field effect transistor T1 controlled via the second normally open contact pair 16 ', which in the exemplary embodiment shown is of the enrichment type or self-blocking. The switching work for switching on and off is carried out here by this MOS field-effect transistor T1 (hereinafter referred to as MOSFET T1), while the first pair of normally open contacts 15 'carries almost only the continuous current.

According to FIG. 4, the diode n1, the anode of which is connected to the one contact of the first pair of normally open contacts 15 ', is led to the cathode of a first bus 23 , furthermore the drain connection of the MOSFET T1, which has one end of the capacitor k1 Resistor r2 in series, the anode of diode n1, a connection of varistor r1 and the cathode of diode n4, the anode of which is connected to the other contact of the first pair of normally open contacts 15 '. A second bus 24 leads from the connection point of the source connection of the MOSFET T1 to the anode of the diode n3, the cathode of which is connected to the one contact of the first pair of normally open contacts 15 ', to the connection point of the varistor r1 and the anode of the diode n2, the cathode of which another contact of the first pair of working contacts 15 'is connected. With the other contact of the second pair of normally open contacts 16 ', the cathode of the diode n1 and a connection point of the resistor r2 are connected to the capacitor k1. The one contact of the second make contact pair 16 'is also connected to the resistor r3, the other end of which leads to the gate connection of the MOSFET T1. Also connected to this gate terminal is one end of the resistor r4, the other end of which is connected to the second bus 24 , and to the cathode of a zener diode 6 , the anode of which leads to the second bus 24 , which also leads to the end facing away from the resistor r2 of the capacitor k1 is connected.

The function of this circuit 22 is as follows: When the relay 2 is de-energized, the two pairs of normally open contacts 15 'and 16 ' are open and the capacitor k1 is charged to the operating voltage of the load circuit via diodes n1-n5 in both AC and DC operation. If the relay d2 is energized, the second pair of normally open contacts 16 'initially closes. The charging voltage of the capacitor k1 is fed to the gate connection of the MOSFET T1 via the second make contact pair 16 'and the resistor r3 and is limited by the zener diode n6. The MOSFET T1 is turned on and the load circuit is turned on via the diode n5, the MOSFET T1 and the diode n2 or via the diode n4, the MOSFET T1 and the diode n3. Shortly thereafter, the first pair of normally open contacts 15 'closes and takes over the load current. The MOSFET T1 discharges the capacitor k1 via the resistor r3. The MOSFET T1 is de-energized as soon as the charging voltage from the capacitor k1 falls below the threshold voltage of the MOSFET T1. The entire load current now flows through the first pair of normally open contacts 15 '.

If the relay d2 is de-energized, its first pair of normally open contacts 15 'opens. The load current continues to flow via the diodes n5 and n1, the uncharged capacitor k1 and the diode n2 or via the diodes n4 and n1 the uncharged capacitor k1 and the diode n3. The capacitor k1 is charged. If the charging voltage now reaches the threshold voltage of the MOSFET T1, which is driven via the second make contact pair 16 'and the resistor r2, the MOSFET T1 is turned on and takes over the load current, as described above.

The voltage at the opening first contact pair 15 'remains insignificant and the occurrence of harmful shutdown spark is prevented, since the shutdown work is largely taken over by the MOSFET T1. If the second normally open contact pair 16 'also opens in the further course, the gate terminal control voltage of the MOSFET T1 drops to zero via the resistor r4. The MOSFET T1 is blocked and the voltage at the capacitor k1 rises until it is limited by the voltage limitation of the varistor r1. The varistor r1 takes over the rest of the shutdown work.

After the shutdown process has ended, the capacitor is k1 recharged to the operating voltage of the load circuit and a new switching process can be initiated. The Self-heating of the load relay is due to the sensible Distribution of the switching process small. It takes the for its electronics necessary control power the load circuit and therefore requires no auxiliary voltage. The circuit arrangement is also not polarity bound and can therefore both AC and DC loads with larger Switch currents largely radio-free.

Fig. 5 shows a variant of the circuit 22 in the form of a circuit 22 ', in which a relay d3 is used, the first make contact pair 25 (with switching element 27 ) is arranged in the course of the load 11 and the AC voltage source 19 and the auxiliary contact pair 26 as a normally closed contact pair (With switching element 28 ) is formed. This means that the normally closed contact pair 26 always opens before the normally open contact pair 25 closes and only then closes after the normally open contact pair has opened again. A special adjustment, as with relay d2, is not required with relay d3.

In the circuit 22 ', in addition to the MOSFET (MOS field effect transistor) T1, a second MOSFET (MOS field effect transistor) T2 is used, but in the exemplary embodiment shown it is of the depletion type, ie is self-conducting. In addition to the second MOSFET T2, the circuit 22 'has been expanded compared to the circuit 22 by the zener diode n7 and the resistor r5. Circuit-specific differences from the circuit 22 result in the following: Between the gate connection of the first MOSFET T1 and the cathode of the diode n1, a zener diode n7 and the source-drain path of the second MOSFET T2 are arranged in series. The source connection of the second MOSFET T2 is connected via the series circuit comprising the resistor r3 and the zener diode n6 to the second bus line 24 ', the connection between the resistor r3 and the cathode of the zener diode n6 being connected to the gate connection of the second MOSFET T2 . The gate connection of the second MOSFET T2 is also connected via the resistor r5 to the other contact of the normally closed contact pair 26 and thus, because of the normally closed normally closed contact, via the one contact of the normally closed contact pair 26 to the second bus line 24 '. This is also connected via the resistor r4, as in the circuit 22 , to the gate connection of the first MOSFET T1.

The mode of operation of this circuit 22 'is as follows: In the idle state of the circuit 22 ', ie when the relay d3 is de-energized, the capacitor k1 is charged, as described with reference to FIG. 4 or the circuit 22 . The gate connection of the second MOSFET T2 is connected to the ground of the circuit 22 'via the closed normally closed contact pair 26 and the low-resistance protective resistor r5. A small current flows through the second MOSFET T2, the high-resistance source resistor r3, the protective resistor r5 and the closed normally closed contact pair 26 to ground. This creates a voltage drop across resistor r3, which leads to a negative control voltage at the gate connection of second MOSFET T2. As a result, the current flow through the second MOSFET T2 is regulated down, and only a voltage arises at the resistor r3 and at the low-resistance protective resistor r5 in series, which corresponds approximately to the threshold voltage of the MOSFET T2. This low voltage is separated by the zener diode n7 from the control circuit of the first power MOSFET T1, so that the control voltage zero is present at its gate connection. The first MOSFET T1 is thus blocked.

If the relay d3 is energized, the normally closed contact pair 26 opens first. The control voltage of the second MOSFET T2 (gate / source) becomes zero and the second MOSFET T2 switches through. The charging voltage of the capacitor k1 is thus switched through to the controlled connection of the second MOSFET T2 and the Zener diode n7 to the gate connection of the first power MOSFET T1. The control voltage at the first MOSFET T1 rises rapidly in a current-controlled manner through the second MOSFET T2 until it is limited to a value by the control circuit formed from the second MOSFET T2, the resistor r3 and the diode n6, which is made up of the Zener voltage of the Zener diode n6 plus the threshold voltage of the second MOSFET T2 reduced by the threshold voltage is formed by the diode n7.

The first power MOSFET T1 becomes live very quickly, since there are low switching losses, and the load circuit is switched through the first MOSFET T1 and the diode n2 via the diode n5 and the first MOSFET T1 and the diode n3 via the diode n4. Only a small voltage is present at the open contact pair 25 of relay d3. After a certain time, the pair of normally open contacts 25 closes and safely takes over the current flow of the load circuit. The capacitor k1 is discharged via the resistor r2 and the first MOSFET T1 until its charging voltage falls below the sum of the threshold voltages from the diode n7 and the first MOSFET T1, so that the latter is blocked.

If the relay d3 is de-energized, the normally open contact pair 25 opens. However, the load current continues to flow via diode n5, diode n1, discharged capacitor k1 and diode n2 or via diodes n4 and n1, discharged capacitor k1 and diode n3. The capacitor k1 is charged. If the charging voltage of the capacitor k1 is now greater than the sum of the threshold voltages of diode n7 and the first MOSFET T1, the latter is turned on as described above and the load current flows again via the diode n1, the first MOSFET T1 and the diode n2 or Via the diode n4, the first MOSFET T1 and the diode n3, so that the voltage at the opening contact pair 25 does not exceed a certain level, thereby effectively preventing the occurrence of a switch-off spark. In the further course, the normally closed contact pair 26 closes again. The current supply of the second MOSFET T2 is almost interrupted, as described at the beginning, the control voltage at the gate connection of the first MOSFET T1 becomes zero, the power MOSFET T1 blocks and the capacitor k1 is charged until the voltage limitation of the varistor r1 starts. The varistor r1 then takes over the rest of the shutdown work. After the switch-off process has subsided, the capacitor k1 is charged again to the operating voltage of the load circuit and a new switching process can be initiated.

The hybrid power relay circuit 22 'according to FIG. 5 enables approximately twice the load current compared to the circuit 22 according to FIG. 4 due to the shorter switching time of the first MOSFET T1. A normally adjusted relay d3 can also be used.

Claims (13)

1. coupling relay circuit, in particular signal transmission relay circuit, with a relay (d1), the excitation winding ( 17 ) and a resistor (r1) are connected to the signal input, characterized in that with the excitation winding ( 17 ) of the relay (d1) and with the resistor (r1) a MOS field-effect transistor (T1) is coupled in such a way that a parallel path to the excitation winding ( 17 ) is open when an input signal is present and closed when there is no input signal. 2. Coupling relay circuit according to claim 1, characterized in that the drain-source path of the MOS field-effect transistor (T1) is parallel to the excitation winding ( 17 ) and the gate connection of the MOS field-effect transistor (T1) with that Excitation winding ( 17 ) opposite end of the resistor (r1) is connected. 3. Coupling relay circuit according to claim 1 or 2, characterized characterized in that the MOS field effect transistor (T1) is self-conducting. 4. Coupling relay circuit according to at least one of the preceding claims, characterized in that the Signal input via a rectifier circuit (n3) between the gate and drain connection of the  MOS field effect transistor (T1) is coupled. 5. coupling relay circuit, in particular signal transmission relay circuit, with a relay (d1), the normally open contact pair ( 13 ) with a capacitor (k3) and a capacitor (k3) associated current limiting resistor (r4) is connected, in particular according to claim 1, characterized in that the Relay (d1) has an auxiliary contact pair ( 14 ) and that a MOS field-effect transistor (T3) is connected between the associated contacts of the normally open contact pair ( 13 ) and the auxiliary contact pair ( 14 ). 6. Coupling relay circuit according to claim 5, characterized in that the auxiliary contact pair is formed by a normally closed contact pair ( 14 ). 7. coupling relay circuit according to claims 5 and 6, characterized in that the relay (d1) is designed such that the normally closed contact pair ( 14 ) opens before the normally open contact pair ( 13 ) closes, and the normally open contact pair ( 13 ) opens before the normally closed contact pair ( 14 ) closes. 8. coupling relay circuit according to at least one of claims 5 to 7, characterized in that the MOS field effect transistor (T3) is normally off.   9. Coupling relay circuit according to claim 8, characterized in that the gate connection of the MOS field effect transistor (T3) on the one contact of the normally open contact pair ( 13 ) facing away from the end of the current limiting resistor (r4) and the source connection of the MOS field effect -Transistor (T3) is connected to the other contact of the normally closed contact pair ( 14 ). 10. coupling relay circuit according to at least one of the claims 5 to 7, characterized in that the MOS field effect transistor (T4) is normally on. 11. Coupling relay circuit according to claim 10, characterized in that the gate connection of the MOS field-effect transistor (T4) on the one contact of the normally open contact pair ( 13 ) facing away from the end of the current limiting resistor (r4) and the source connection on the other contact of the Working contact pair ( 13 ) is connected. 12. Coupling relay circuit according to at least one of claims 5 to 11, characterized in that a Zener diode (n6) is arranged between mutually associated contacts of the work and normally closed contact pair ( 13 , 14 ). 13. Coupling relay circuit, characterized by the Combination of the features of claim 1 and possibly at least one of claims 2 to 4 and those of Claim 5 and possibly at least one of claims 6 to 12th