NO853152L - SAFETY SWITCH. - Google Patents

Description

The present invention relates to a safety switch, in particular

such a switch that includes a plug contact and a plug to be plugged into another zig contact, and with a fault current device and a protective switch arranged to break the current circuit that is to be closed or has been closed in the event of a detected fault current.

There are known safety switches designed as plug-in contacts and where the protective switch is activated by a control current when a fault current is detected and thereby transferred to the cut-off position. Such plug-in connectors have the disadvantage that a control current is necessary to trip the protective switch. This constitutes an uncertainty factor. If the uncontrollable control current were to drop out, protective tripping in the event of a detected fault current is ruled out. Fault current detection involves a detected current difference between the conductor leading to the relevant consumer device and the return conductor from the device.

It is therefore an object of the present invention to produce a safety switch of the type indicated above, but where release

one of the protective switches in case of detected fault current takes place without control current.

This purpose is achieved by a safety switch whose distinctive feature according to the invention is that the fault current device is connected to an electromagnet, which comprises a coil and a magnetic core, the coil being in electrical connection with the fault current device and the core being in mechanical connection with the protective switch, and the protection switch is arranged so that, in the event of a tripping coil as a result of a detected fault current, and is brought into the disconnection position by means of a draw spring, and the current-loaded coil is arranged so that when the core is pulled in and the draw spring is energized, the protection switch is switched from the cut-off position to the cut-in position by means of a setting mechanism.

According to the invention, the transfer of the protective switch to the cut-off position when fault current is detected takes place mechanically, so that the otherwise usual uncertainty factor constituted by the control current is eliminated. Below, the electromagnet's coil is dimensioned so that the magnetic core cannot be pulled into the coil from the protection switch's cut-off position against the action of its pull spring, but only "sticks"

in the current-loaded coil and is consequently retained by the coil when this is transferred from the cut-off state for the protective switch to the switch-on state for the switch by means of the setting mechanism. As soon as a fault current is detected by the fault current device, the coil is de-energized, so that the core either cannot be retained by the coil at all or is quickly pulled out of the coil under the influence of the draw spring, so that the protective switch either remains in the cut-off position or is returned to this position. In both cases, it is ensured that the coil of the electromagnet must always be brought back to a state corresponding to the tripping of the protection switch, when the core and thus the protection switch is to be transferred to the switch's switch-on position. This prevents e.g. a connected consumer device, if rubbish is inserted into the plug socket, can take up power without further ado when a previously detected fault current is no longer present and consequently the coil is again excited over the fault current device. Furthermore, also in this case, the core of the electromagnet remains in a position which corresponds to the switch-off of the protection switch and must thus be transferred by the excited coil to the switch-on position for the protection switch. This is only achieved by the process that the coil is brought out of the switch-on state and into a state corresponding to the switch-off of the protection switch and back again by means of the externally operable setting mechanism and consequently only carried out by an operator.

With regard to particulars, there are several possibilities for appropriate design and further development of the safety switch according to the invention, which is only shown in the following by various design examples.

Firstly, according to the invention, a rotatable weight arm can be articulated with the core of the electromagnet on one side and with the firmly anchored tension spring on the other side, while the weight rod between the two connection points is rotatably arranged on a switch shaft for the protection switch and strikes against a stop when the core is driven out from said coil. Thereby, the mutual coordination of core and coil is maintained even when the core emerges from the coil. In addition to this, a relatively simple mechanism designed as a weight arm drive is used to operate the protection switch.

In a preferred embodiment of the safety switch according to the invention, the coil of the electromagnet is arranged on

a sliding body which is introduced into the switch housing and in the switch-on position of the protective switch is effectively influenced by a tension spring and by a spring-loaded locking arm, the locking arm being pivotally supported and entering the locking position in engagement with a locking projection on the sliding body. Consequently, the coil or its sliding body can only be brought back to renewed absorption of the core by operating the setting mechanism in the protection switch's cut-out position, and for this purpose it is necessary to transfer the locking arm to a position where its locking action is cancelled.

A further preferred embodiment of the safety switch

according to the invention has as a distinctive feature that the setting mechanism has a rotary knob which is accessible on the outside of the switch housing and is provided with a gear on its bearing shaft, said gear engaging with a rack on the sliding body. In the rotary knob, a push rod which is guided through the hollow bearing shaft is axially displaceable against spring action to cancel the locking condition, as this locking rod in the axially displacing position pushes the locking arm back to the unlocked position.

The rotary knob therefore serves on the one hand to move the sliding body or coil and on the other hand occupies the push rod for releasing the locking arm from its locking position.

Finally, a preferred embodiment of the safety switch is

according to the invention, characterized in that the switch housing with the fault current device, the protective switch, the electromagnet and the setting mechanism is designed as a separate module for insertion into the plug socket.

The advantages achieved by the present invention can be summarized in the fact that a safety switch has been achieved, in particular such a switch which includes a plug socket and a plug for plugging into another plug socket, and where triggering of the protective switch can take place without control current, since a mechanical influence of the circuit breaker is ensured by fault current detection by a relatively simple and functionally reliable construction of the safety switch. In the case of the safety switch according to the invention, the protection switch thus actually functions independently of a common source of error in previously known technology, namely independently of any control current.

In the following, the invention will be explained in more detail with the help of an embodiment and with reference to the attached drawings, on which: fig. 1 schematically shows the working function of a safety switch according to the invention and made as a plug contact, the switch position before fault current exposure is recorded with solid lines, and with dashed lines after fault current detection. Fig. 2 shows a side view of a building module for the item in fig. 1, and with fault current device, protection switch, electromagnet and setting mechanism. Fig. 3 shows a view from above of the indicated item in fig. 2 with the rotary knob removed.

Fig. 4 shows the object in fig. 2 seen from the bottom.

Fig. 5 shows the object in fig. 2 with the protection switch in the switch-on position. Fig. 6 shows the object in fig. 3 with the protection switch in the switch-on position.

In the figures, a safety switch designed as a plug socket 1 is shown, as well as equipped with a plug that can be inserted into a wall plug socket, the safety switch having a fault current device 2 which is connected to two electrical conductors, as well as a protection switch switched on in the conductors 3, so that the protective switch 4 breaks the current circuit that is to be closed or has been closed in the event of detected fault current.

An electromagnet with a coil 5 and a core 6 is connected to the fault current cleaner 2, the coil 5 being in electrical connection with the fault current device while the magnetic core 6 is in mechanical connection with the protection switch 4, so that the protection switch 4 when de-energized coil 5 as a result of a detected fault current is brought into the cut-off position by means of a tension spring 7 which engages with the magnetic core 6.

The current-loaded or excited coil 5 for the electromagnet can, during absorption of the introduced core 6 and tension of the tension spring 7, be transferred from a state corresponding to a switched-off protection switch to a state corresponding to a switched-on protection switch by means of an externally actuable setting mechanism. To the core 6 for the electromagnet on the one hand and to the stationary anchored tension spring 7 on the other hand, a pivotable weight rod 9 is articulated, which between the two connection points is rotatably supported on a coupling shaft 10 for the protective switch 4, as the magnetic core 6 during its movement out of the coil 5 hits a stop 11, which prevents any further movement of the core 6 out of the coil. The coil 5 is arranged on a sliding body 13 which is guided into the switch housing 12, and which, in the switch-on position of the protection switch, is effectively affected by a return spring 14 and a spring-loaded locking arm 15, the locking arm 15 being pivotally supported in the switch housing 12 and in the locked position is engaged with a locking projection 16 on the sliding body 13.

The setting mechanism has a rotary knob 8 which is accessible on the outside of the switch housing 12 and is equipped with a gear wheel 17 on a storage shaft, the gear wheel being engaged with a rack 18 on the sliding body 13. In the rotary knob 8 is a push rod 19 which is passed through the knob's cavity bearing shaft axially displaceable against spring action to lift the locking, as the push rod 19 in its axially forward-pushing or depressed position pushes the locking arm 15 back to the unlocked position.

The switch housing 12 with the residual current device 2, the protective switch 4, the electromagnet and the setting mechanism is designed as a module for insertion into the plug socket 1.

Claims (5)

1. Safety switch, in particular a switch comprising a plug-in socket and a plug to be inserted into another plug-in socket, and with a fault current device (2) and a protective switch (4) arranged to break the circuit which is to be closed or has been closed by detected fault current, characterized in that the residual current cleaning device (2) is connected to an electromagnet comprising a coil (5) and a magnetic core (6), the coil (5) being in electrical connection with the residual current device (2) and the core (5) being in mechanical connection with the protective switch (4), as well as the protective switch (4) is designed to be brought into the cut-off position by means of a tension spring (7) in the event of a tripping coil (5) as a result of a detected fault current and the current-loaded coil (5) is designed to be in the case of a retracted core ( 6) and tension of the tension spring (7) to change the protective switch (4) from the cut-off position to the cut-in position by means of a setting mechanism. 2. Safety switch as specified in claim 1, characterized in that a pivotable weight arm (9) is connected to the core of the electromagnet (6) on the one side and to the firmly anchored tension spring (7) on the other side, which is between the two connection points is rotatably supported on a switch shaft (10) for the protection switch (4) and strikes against a stop (11) when the magnetic core (6) is moved out from the coil (5). 3. Safety switch as stated in claim 1 or 2, characterized in that the electromagnet's coil (5) is arranged on a sliding body (13) which is introduced into the switch housing (12) and in the switch-on position of the protection switch is effectively influenced by a reset spring (14) and a spring-loaded locking arm (15), in that the locking arm (15) is pivotally supported and its locking position engages with a 1-eye projection (16) on the sliding body (13). 4. Safety switch as specified in claims 1-3, characterized in that the setting mechanism has a rotary knob (8) which is accessible on the outside of the switch housing (12) and is provided with a gear wheel (17) on its bearing shaft and which engages with a toothed rack (18) on the sliding body (13), while in the rotary knob (8) there is arranged a push rod (19) which is guided through the hollow bearing shaft of the rotary knob, and is axially displaceable against spring action, and in its axially displaceable position presses back the locking arm ( 15) to lock-free position. 5. Safety switch as specified in claims 1-4, characterized in that the switch housing (12) with the fault current device (2), the protective switch (4), the electromagnet and the setting mechanism is designed as a building module for insertion into the plug socket (1).