EP1036398A1 - Electromagnetic relay - Google Patents

Abstract

The invention relates to an electromagnetic relay, comprising a magnetic system (6) with an exciting field coil (WR), a core and an armature. Each load current circuit can be closed by a movable contact element and by at least one fixed contact element. A reed contact (KR) is coupled to a load current conductor (1) in each load current circuit. Means to generate and process an overcurrent signal and to disconnect the control current are coupled to the reed contact (KR).

Description

description

Electromagnetic relay

The invention relates to an electromagnetic relay which is short-circuit and overload-proof.

In conventional solutions for ensuring a short-circuit or overload resistance for a relay, protective devices are predominantly used which interrupt the load current in the event of a fault using thermal effects. These include in particular fuses or bimetallic contact springs.

From SU 142 74 72 AI a short-circuit protection for a three-phase motor is known, which is realized with the help of reed relays. However, the reed relays are arranged there separately from the motor relays. In particular, it is not possible to query an overload or short-circuit status for the motor relays that switch on the motor power supply.

The invention is based on the objective of creating a cost-effective, integrated and, in particular, space-saving solution for a short-circuit or overload-proof relay, in particular a differentiated response of the protective devices in the event of a permanent overload of the relay and not being desired even with only brief current peaks.

According to the invention, this goal is achieved with an electromagnetic relay

a magnet system containing an excitation coil through which a control current flows, a core and an armature, the core and the armature forming at least one working air gap, - at least one movable contact element and minde ^¬ least one fixed contact member, by which each ^¬ weils a load current circuit can be closed,

- coil and contact connection elements,

one reed contact per load circuit, which is coupled to a load current conductor through which a load current flows, and

- Means for generating and processing an overcurrent signal and for switching off the control current. ^■

A relay according to the invention can be reset to a normal operating state by interrupting the control current. Compared to Hall sensors, which also allow detection of a magnetic field emanating from an increased load current, reed contacts offer the advantage of temperature-independent behavior, simple setting of trigger threshold values and easy-to-implement evaluation circuits.

Advantageous embodiments with regard to the arrangement of the

The reed contact relative to the load current conductor, the shielding of the reed contact from the magnetic field of the excitation coil and the means for generating and processing the overcurrent signal and for switching off the control current can be found in the dependent claims.

The invention is explained in more detail below using exemplary embodiments with reference to the drawing. 1 shows a relay according to the invention with a reed contact preassembled on a printed circuit board,

2 shows the reed contact preassembled on a printed circuit board with a coupled load current conductor according to FIG. 1, FIG. 3 shows a variant of a relay according to the invention with a reed contact inserted into a base, FIG. 4 shows the reed contact inserted into a base with a coupled load current conductor according to FIG. 3, 5 shows a further variant of a relay according to the invention with a reed contact preassembled on a base, FIG. 6 shows the reed contact preassembled on a base with a coupled load current conductor according to FIG. 5, FIG. 7 shows a basic circuit diagram of a relay according to the invention with an auxiliary reed contact and an auxiliary winding as overcurrent protection elements,

8 shows a basic circuit diagram of an embodiment with an auxiliary relay as an overcurrent protection element, FIG. 9 shows a basic circuit diagram of a further embodiment with a PTC thermistor and a series resistor as overcurrent protection elements,

10 shows a basic circuit diagram of a bistable embodiment with a capacitor as a pulse control element, FIG. 11 shows a basic circuit diagram of an embodiment with evaluation electronics for overcurrent detection and load current shutdown and

12 shows a realization of the evaluation electronics according to FIG. 11.

1 to 6 show variants of a relay according to the invention with different coupling of a reed contact K _R to a load current conductor 1. In the embodiment according to FIG. 1, the reed contact K _{R is} preassembled on a printed circuit board 4. A magnet system 6 is arranged on a base 5 and has a core, an armature and an excitation coil W _R. The axis of the excitation coil _R extends parallel to the base plane of the base 6. In an outer area on the base 5, the printed circuit board 4 is fastened in a position perpendicular to the base plane of the base 5. Two connection plates 2 and 3 are connected to the reed contact K _R (see also FIG. 2). Switching thresholds for the reed contact K _R can be defined by a suitable choice of the distance between the two connecting plates 2 and 3. The two conductor connection plates 2 and 3 are fitted together with the reed contact K _R on a printed circuit board 4, the reed contact K _{R being} oriented perpendicular to the base plane of the base 5 is. According to a preferred embodiment of the reed contact _R K is thus arranged perpendicular to the axis of the excitation coil W _R, whereby the reed contact _R K against the magneti ^¬'s leakage flux of the excitation coil W _R is insensitive. The load current conductor 1 is in a section perpendicular to the reed contact ^¬ K _R arranged, being ensured by an appropriate conductor configuration that the magnetic field generated by the load current conductor 1 passes through the reed contact _R K centrally and parallel. In this embodiment, this is achieved in that the relevant section of the load current conductor 1 is formed by a sheet metal strip, the sheet metal plane of which extends parallel to the reed contact K _R.

In the embodiment shown in Figure 3, the magnet system 6 is arranged on the base 5 that the

Axis of the excitation coil W _{R runs} parallel to the base plane of the base 5. The reed contact K _R is mounted between the magnet system 6 and the base 5 perpendicular to the axis of the excitation coil W _R and parallel to the base plane of the base 6. In this embodiment too, the reed contact K _{R is} two

Contacting plates 2 and 3 connected (see also Figure 4). The two contact plates 2 and 3 are at a distance from one another which determines the switching threshold of the reed contact K _R. The unit formed from the contacting plates 2 and 3 and the reed contact K _R is inserted into the base 5, the load current conductor 1 being inserted in one section in the middle through a sensor ring R _s formed from the reed contact K _R and the contacting plates 2 and 3. In this section, the load current conductor 1 is formed by a bent sheet metal strip, so that the sensor ring R _s lies at a free end of the sheet metal strip perpendicular to the load current conductor 1 and encloses it. As an alternative to the example shown in FIG. 4, the sensor ring R _{s can} also be formed by a U-shaped, magnetically conductive flux ring and a reed contact K _R coupled to it via two air gaps. O

Figure 5 shows an embodiment of a relay with a pre-mounted on a pedestal 5 reed contact K _R, said reed contact K _R perpendicular to the base plane of the base 5 is orien ^¬ advantage. In this exemplary embodiment, the magnet system 6 is mounted on the base 5 such that the axis of the excitation coil W _R extends parallel to the base plane of the base 5. The load current conductor 1 is essentially formed by a sheet metal strip, a first end of the load current conductor 1 being inserted vertically through the base as a connecting element. The second end of the load current conductor 1 runs parallel to the axis of the excitation coil W _R (see also FIG. 6). In a central section, the load current conductor 1 is formed into a loop surrounding the reed contact K _R. A corresponding shaping of the load current conductor 1 in this central section ensures that the magnetic field coupled into the reed contact K _R by the load current conductor 1 passes through the reed contact K _{R in the} center and in parallel. The reed contact K _R is bent together with its connecting wires in a U-shape and fastened with the ends of the connecting wires to extensions of two connecting loops 7 and 8. The reed contact K _{R can be connected} to the extensions of the connection loops 7 and 8 arranged below the magnet system 6, for example by soldering or resistance welding. The distance between the two connection loops 7 and 8 defines the switching threshold of the reed contact K _R. In all of the exemplary embodiments shown in FIGS. 1 to 6, there is an advantage in that the assembly of the reed contact K _R and the coupling of the reed contact K _R to the load current conductor 1 do not require any significant design changes to the relay.

FIG. 7 shows a basic circuit diagram of a relay with an auxiliary reed contact and an auxiliary winding as overcurrent protection elements. The relay R has a control circuit, which is associated with an excitation winding W _R through which a control current I _s is assigned, and a load circuit, the load current I _L through a movable contact element K _B and a fixed contact element K _{F of} the relay R is controllable. A reed contact K _{R is} arranged in the control circuit, through which the control current I _s can be controlled by the excitation coil W _R. The reed contact K _R is coupled to a load current conductor through which the load current I _L flows. The magnetic coupling between the load current conductor and the reed contact K _R is subsequently symbolized by a load current conductor winding W. In the exemplary embodiment according to FIG. 7, the reed contact K _{R has} a movable contact element E1 and two stationary contact elements E2 and E3. Furthermore, one

_Auxiliary winding W _Hι coupled to the reed contact K _{R in} such a way that in an overcurrent _{operating state} the auxiliary winding W _H ι emits a magnetic field which is in the same direction as a magnetic field caused by a load current _conductor winding W.

The load current I _L is switched directly via the movable contact element K _B and the fixed contact element K _{F of} the relay R. The reed contact K _R can be arranged axially within the load current winding W. A reed contact K _R lying outside the load current winding W _L , which is arranged parallel to the winding axis, is also possible. An alternative to coupling the reed contact K _R to a load current winding W _L is to arrange the reed contact K _R within a loop-shaped section of a load current conductor.

In order to prevent interference of the reed contact _R K by the magnetic field of the excitation coil W _R of the relay R, the clock K _R Reedkon- advantageously perpendicular to the axis to arrange the excitation coil W _R. Alternatively, the aforementioned influence can be prevented by a magnetically conductive shielding plate between the excitation coil W _R and the reed contact K _R. A magnetic stray field originating from the excitation coil W _{R is} short-circuited by the shielding plate. Another possibility is to specifically direct the magnetic stray flux emanating from the excitation coil W _R into the reed contact K _R initiate. This is possible, for example, by regulating the control current I _s . As a result, a constant magnetic flux acts as an offset on the reed contact K _R. By Defini ^¬ tion corresponding threshold values at the reed contact K _{R is} a utilization of the stray magnetic field is thus possible.

In a normal operating state, the reed contact K _R connects the excitation coil W _{R of} the relay R via a first fixed contact element E2 of the reed contact K _R to a control voltage source U _s . In this state, the auxiliary winding W _H coupled to the second fixed contact element E3 is separated from the movable contact element El of the reed contact K _R and thus from the control voltage source U _s . In an overcurrent operating state, on the other hand, the movable contact element El of the reed contact K _{R is} connected to the second fixed contact element E3 and separated from the first fixed contact element E2. As a result, the excitation winding W _{R of} the relay R is separated from the control voltage source U _s , while the auxiliary winding W _{H is} connected to the control voltage source U _s . Even after the load circuit is interrupted, the connection between the movable contact element E1 of the reed contact K _R and the second fixed contact element E3 is maintained due to the magnetic flux emanating from the auxiliary winding W _H. The relay R only returns to the normal operating state after disconnection from the control voltage source U _s .

FIG. 8 shows a basic circuit diagram of an alternative design option for a short-circuit-proof relay, in which the overcurrent protection function is implemented by means of an auxiliary relay R _H ι. The auxiliary relay R _H1 has a movable contact element E4 and two fixed contact elements E5 and E6, the movable contact element E4 being connected to the first fixed contact element E5 in the normal operating state. The movable contact element E4 is connected directly to a control voltage input terminal, so that the control voltage U _s directly at the excitation coil W _{R of} the relay R O

is present. The reed contact K _R is connected between the contact element E4 of the auxiliary relay R _H ι and the second fixed contact ^¬ element E6.

The coil W _{H2 of} the auxiliary relay R _H ι is de-energized in the normal operating state. In the overcurrent operating state, the reed contact K _{R is} closed, as a result of which the control voltage U _{s is applied} directly to the coil W _{H2 of} the auxiliary relay R _H ι. As a result, the movable contact element E4 is connected to the second fixed contact element E6 of the auxiliary relay R _H ι and separated from the first fixed contact element E5. Because of this, the excitation coil W _{R of} the relay R is de-energized in the overcurrent operating state. Because the load circuit and the control circuit of the auxiliary relay R _H ι are connected in series in the overcurrent operating state, the auxiliary relay R _H. even after interrupting the load circuit of the relay R by actuating the contact element K _B and the associated opening of the reed contact K _R its switching position. If a time delay unit is additionally arranged between the reed contact K _R and the second fixed contact element E6 of the auxiliary relay R _H ι, short-term load current peaks do not trigger the overcurrent protection device. Instead of the auxiliary relay R _H ι, a second reed contact can be used, which is then coupled to an associated auxiliary winding.

FIG. 9 shows a further alternative for implementing overcurrent protection with a _PTC thermistor R _PTC and a series resistor R _{v connected in series} . These two overcurrent protection elements are in series with the reed contact K _R on the

Control voltage source U _s connected, the reed contact K _{R being} initially closed in the overcurrent operating state and opened in the normal operating state. The excitation coil W _{R of} the relay R is connected in parallel to the reed contact K _R and the series resistor R _v and in series with the PTC thermistor R _PT c. Since the series resistor R has a low resistance compared to the internal resistance of the excitation coil W _{R of} the relay R, an increased current SEN of the reed contact _R K through the cold conductor ^¬ R _PTC whereby this heated and becomes high impedance. As a result, the voltage drop at the excitation coil W _{R of} the relay decreases, so that the load circuit is interrupted. Depending on the heating behavior of the _PTC thermistor R _PTC , a time delay is reached, which means that short-term load current peaks do not trigger protection. In addition, the _PTC thermistor R _PTC performs a status memory function if the residual current through the excitation coil W _{R of} the relay R is sufficient to achieve the required level

Maintain PTC temperature. In this case, the _PTC thermistor R _PTC remains in a high-resistance state even after the reed contact K _{R is} reopened. Only after disconnection from the control voltage _source U _s and cooling of the _PTC thermistor R _PTc can the relay R be _activated again.

10 shows a basic circuit diagram of an embodiment with a bistable relay R ₂ s and a capacitor C _s . The bistable relay R _2S is equipped with a first field winding W _R1 and a second field winding W _R2 . The first excitation winding W _{R1 of} the relay R _2S is connected in series with the capacitor C _s to the control voltage source U _s . The second field winding W _R2 is connected in series with the reed contact K _R to the control voltage source Us and has an opposite winding direction compared to the first field winding W _RJ . A positive pulse of the current I _S1 through the first field winding W _R1 thus causes the load circuit to close, while a positive pulse of the current I _s2 through the second field winding W _R2 interrupts the load circuit. In the event of an overcurrent, the reed contact K _R first connects the second excitation winding W _R2 to the control voltage source U _s , whereupon the relay R ₂ s changes into a stable switched-off state. Only after the control voltage U _s is switched off and on again does the first excitation winding W _{Rα receive} a positive current pulse via the capacitor C _{s, as} a result of which the relay R _{2S changes} to a stable switched-on state.

gerspulen W _R switched, while the second resistor R3 of the opening U3 between the first excitation coil connection K3 and the second reed contact connection K4 is connected.

The timing element U1 has a comparator CMP and an RC element, the capacitor C1 of the RC element being connected to the first control voltage terminal Kl by a first connection. The resistor R1 of the RC element is connected between the second terminal K5 of the capacitor C1 and the second reed contact terminal K4. The comparator CMP itself consists of a pnp transistor T2 and a Zener diode Dl, the transistor T2 of the comparator CMP having its emitter connected to the first control voltage terminal Kl, while the collector of the transistor T2 is connected to the base of the transistor TI of the switch-on path U2 . The base of the transistor T2 of the comparator CMP is connected to the cathode of the Zener diode Dl, the anode of which is connected between the capacitor Cl and the resistor Rl of the RC element.

When the control voltage U _{s is applied} to the control voltage connections Kl and K2 of the electronic circuit CCU, a control current flows across the emitter-base path of the transistor TI of the switch-on path U2 and switches the transistor TI on. As a result, the excitation coil W _{R of} the relay R is supplied with a switching voltage, whereupon the load circuit is closed. The transistor TI is switched via the resistor R2, the switching speed of the transistor playing an important role. Before activating the timing element Ul, it must be ensured that the relay R switches through first when the control voltage U _{s is} applied. The timing element U1 has the task of blocking the transistor T2 of the comparator CMP until the transistor TI of the switch-on path U2 is turned on. The transistor T2 of the comparator CMP then changes to a stable, blocked state, which is achieved by the feedback of the Collector voltage of the transistor Tl is reached via the resistors R3, Rl and via the Zener diode Dl.

In the event of an overcurrent, the reed contact K _R closes and connects the base of the transistor T2 directly to the second control voltage connection K2. This causes the capacitor Cl to discharge through the resistors Rl and R3. After exceeding the breakdown voltage at the Zener diode Dl, a control current flows through the emitter-base path of the transistor T2, which turns on the transistor T2 and the base of the

Transistors T1 of the switch-on path U2 electrically connects to the first control voltage terminal Kl. The switch-off path U3 is then activated via the transistor T2 of the timing element U1, as a result of which the transistor T1 of the switch-on path U2 changes to the blocked state. As a result, the

Excitation coil W _{R of} the relay R separated from the control voltage source U _s , so that the load circuit is interrupted. The result of this is that the reed contact K _R opens again, since no overcurrent now flows through the load circuit. The switch-off path U3 remains activated since the transistor T2 of the comparator CMP remains in the conductive state. This operating state is maintained or stored until the control voltage U _s at the control voltage connections Kl and K2 of the electronic circuit CCU is switched off.

An undesired response of the overcurrent protection device at inrush or switchover current peaks, which are generally less than a few 100 milliseconds, is prevented by the timing element U1. By appropriately dimensioning the resistor Rl, the capacitor Cl of the timer element Ul, the resistors R3 and R4 of the switch-off path U3 and by selecting a Zener diode Dl with a suitable breakdown voltage, the timing behavior of the electronic circuit CCU can be adapted to the duration of the expected switch-on or Switching current peaks can be adjusted. At the same time, through the timing element Ul also filtered out interference pulses at the control voltage connections K1 and K2.

Claims

claims

1. Electromagnetic relay with

a magnet system (6) containing an excitation coil (W _R ) through which a control current (I _s ) flows, a core and an armature, the core and the armature forming at least one working air gap,

at least one movable contact element (K _B ) and at least one fixed contact element (K _F -), by means of which a load circuit can be closed,

- coil and contact connection elements,

- a reed contact (K _R ) per load circuit, which is coupled to a load current conductor (1) through which a load current (I _L ) flows, and - means coupled to the reed contact (K _R ) for switching off the control current (I _s ), characterized that these means generate and process an overcurrent signal.

2. Relay according to claim 1, characterized in that the reed contact (K _R ) is integrated in an electrically and magnetically conductive, open flux ring which surrounds the load current conductor (1).

3. Relay according to claim 1, characterized in that the reed contact (K _R ) to an electrically and magnetically conductive, open flux ring, which surrounds the load current conductor (1), is coupled via two air gaps.

4. Relay according to claim 1, characterized in that the load current conductor (1) is formed in a section into a loop which surrounds the reed contact (K _R ).

5. Relay according to one of claims 1 to 4, characterized in that the load ^¬ current conductor (1) is arranged in a section perpendicular to the reed contact (K _R ), wherein the load current conductor (1) in the reed contact (K _R ) coupled magnetic River passes through the reed contact (K _R ) in the middle and in parallel.

6. Relay according to claim 1, characterized in that the load current conductor (1) is wound in one section into a coil (W _L ), the reed contact (K _R ) being arranged axially in the coil (W _L ) .

7. Relay according to claim 1, characterized in that the load current conductor (1) is wound in one section to form a coil (W _L ), the reed contact (K _R ) being arranged outside the coil (W _L ) parallel to its axis .

8. Relay according to one of claims 1 to 7, characterized in that the reed contact (K _R ) is arranged perpendicular to the axis of the excitation coil (W _R ).

9. Relay according to one of claims 1 to 7, characterized in that a magnetically conductive sheet is arranged between the reed contact (K _R ) and the excitation coil (W _R ).

10. Relay according to one of claims 1 to 7, characterized in that the excitation coil (W _R ) is coupled to a current regulator for introducing a defined magnetic flux into the reed contact (K _R ).

11. Relay according to one of claims 1 to 10, characterized in that the means for generating and processing the overcurrent signal and for switching off the control current (I _s ) are combined to form an overcurrent protection unit.

12. Relay according to claim 11, characterized in that the reed contact (K _R ) has a movable contact element (El) and two fixed contact elements (E2, E3) that the overcurrent protection unit by one coupled to the reed contact (K _R ) Auxiliary winding (W _H ι) is formed that the movable contact element (El) of the reed contact (K _R ) is connected to a first control voltage connection, that a first connection of the excitation coil (W _R ) with a first fixed contact element (E2) Reed contact (K _R ) is connected that a first connection of the auxiliary winding (W _H ι) is connected to the second fixed contact element (E3) of the reed contact (K _R ), that the second connection of the excitation coil (W _R ) and the second connection the auxiliary winding (W _H ι) are connected to the second control voltage connection, that the movable contact element (El) of the reed contact (K _R ) in a normal operating state with the first fixed contact elements t (E2) of the reed contact (K _R) is connected, and that the movable Liehe contact element (El) is connected to the reed contact (K _R) in an overcurrent operating state with the second fixed contact element (E3) of the reed contact (K _R).

13. Relay according to claim 12, characterized in that the auxiliary winding (W _H ι) is coupled to the reed contact (K _R ) in such a way that in the overcurrent operating state of the current-carrying auxiliary winding (W _H ι) a magnetic field emanates from the reed contact (K _R ) is in the same direction as the magnetic field caused by the load current (I _L ).

14. Relay according to claim 11, characterized in that the overcurrent protection unit is formed by an electromagnetic switching unit which has a movable contact element (E4), two fixed contact elements (E5, E6) and a coil (W _H2 ) that the movable contact element (E4) of the switching unit is connected to a first control voltage connection, that a first connection of the excitation coil (W _R ) is connected to a first fixed contact element (E5) of the switching unit, that a first connection of the coil (W _H2 ) of the switching unit is the second fixed contact element (E6) of the switching unit is connected, that the second connection of the excitation coil (W _R ) and the second connection of the coil (W _H2 ) of the switching unit are connected to the second control voltage connection, that the reed contact (K _R ) is connected between the first control voltage connection and the first connection of the coil (W _H2 ) of the switching unit that the movable he contact element (E4) of the switching unit is connected to the first fixed contact element (E5) of the switching unit in a normal operating state, and that the movable contact element (E4) of the switching unit is connected to the second fixed contact element (E6) of the switching unit in an overcurrent operating state .

15. Relay according to claim 14, characterized in that a time delay unit is connected between the reed contact (K _R ) and the coil (W _H2 ) of the switching unit.

16. Relay according to claim 14 or 15, characterized in that the electromagnetic switching unit is realized by an auxiliary relay (R _H ι).

17. Relay according to claim 14 or 15, d a d u r c h g e k e n n z e i c h n e t that the electromagnetic switching unit is realized by an auxiliary reed contact.

18. Relay according to claim 11, characterized in that the overcurrent protection unit is realized by a PTC thermistor (R _PT c) and a series resistor (R _v ), which in series with the reed contact (K _R ) to the control voltage source (U _s ) are connected, that the reed contact {K _R ) is open in a normal operating state and closed in an overcurrent operating state, and that the relay coil (W _R ) is parallel to the reed contact (K _R ) and to the series resistor (R _v ) as well as serially to the PTC thermistor (R _PT c) is switched.

19. Relay according to claim 11, characterized in that the overcurrent protection device is integrated in the magnet system (6), which has an additional second excitation coil (W _R2 ) for realizing two stable switching states, the excitation coils (W _R ι, W _R2 ) are wound in opposite directions and a control current (I _S ι) through the first coil (W _R1 ) puts the relay into an on state, while a control current (I _S2 ) through the second coil (W _R2 ) changes the relay into an off state that the first coil (W _{R:) is connected} in series to a capacitor (C _s ) to the control voltage source (U _s ), and that the second coil (W _R2 ) is connected in series to the reed contact (K _R ) to the control voltage source ( U _s ) is connected.

20. Relay according to claim 11, characterized in that the overcurrent protection device is implemented by an electronic circuit (CCU) which has a first control voltage connection (Kl) and a second control voltage connection (K2), and in that the circuit (CCU) has a timing element ( Ul), egg ne switch-on distance (U2) for the excitation coil (W _R ) and a switch-off distance (U3).

21. Relay according to claim 20, characterized in that the switch-on path (U2) for the excitation coil (W _R ) from a series to the excitation coil (W _R ) between the two control voltage connections (K1, K2) connected pnp transistor (Tl) and one Series resistor (R2) is that the transistor (T1) of the switch-on path (U2) with its emitter on the first

Control voltage connection (Kl) and with its collector connected to a first excitation coil connection (K3), that the excitation coil (W _R ) is connected with its second connection to the second control voltage connection (K2), and that the series resistor (R2) of the switch-on path (U2) is connected between the base of the transistor (Tl) of the switch-on path (U2) and the second control voltage connection (K2).

22. Relay according to claim 21, characterized in that the switch-off path (U3) for the excitation coil (W _R ) is formed by a first resistor (R4) and a second resistor (R3) in that the first resistor (R4) of the switch-off path (U3 ) is connected in parallel to the excitation coil (W _R ), that the reed contact (K _R ) is connected with a first connection to the second control voltage connection (K2), and that the second resistor (R3) of the switch-off path (U3) between the first connection (K3 ) the excitation coil (W _R ) and the second connection (K4) of the reed contact (K _R ) is connected.

23. Relay according to claim 22, characterized in that the timing element (Ul) has a comparator (CMP) and an RC element, that the capacitor (Cl) of the RC element is connected to the first control voltage connection (Kl) with a first connection and that the resistance (Rl) of the RC element between the second connection (K5) of the capacitor (Cl) and the second connection (K4) of the reed contact (K _R ) is connected.

24. Relay according to claim 23, characterized in that the comparator (CMP) consists of a pnp transistor (T2) and a Zener diode (Dl) in that the transistor (T2) of the comparator (CMP) with its emitter at the first control voltage connection (Kl ) is connected that the transistor (T2) of the comparator is connected with its collector to the base of the transistor (Tl) of the switch-on path (U2), that the transistor (T2) of the comparator is connected with its base to the cathode of the zener diode (Dl) is connected, and that the Zener diode (Dl) is connected with its anode between the capacitor (Cl) and the resistor (Rl) of the RC element.