DE8806830U1 - Backup - Google Patents

Description

The innovation concerns a fuse for disconnecting a power cable according to the generic term of claim 1.

Such fuses are generally referred to as automatic circuit breakers and have a snap mechanism that opens a mechanical switch when a permissible current is exceeded. This snap mechanism can also be triggered from the outside using a push button. Another actuating element is used to switch the fuse back on, which simultaneously indicates the triggered state when the fuse pops out.

With the known safety device, not only is the mechanism complicated and complex, but there is also the disadvantage that

that after the fuse has blown, if the corresponding circuit is open, there is naturally no light available and the fuse in question cannot be found if the circuit associated with this fuse also supplies the lighting which is installed near the fuse box.

Based on the above-mentioned state of the art, the aim of the present innovation is to further develop a safety device of the type mentioned at the outset in such a way that improved operability of the arrangement is achieved through a simpler construction.

This problem is solved by the features specified in the characterising part of the main claim.

In particular, when the fuse is triggered, i.e. when the associated circuit is interrupted, an emergency lighting element lights up, which either illuminates the location where the fuses are located or identifies the triggered fuse itself, so that the user can easily find the fuse and (after eliminating the short circuit) switch it back on.

2g Preferably, the electrical actuating means for triggering the fuse comprise a first magnet which is attached to the actuating member for the switch, and an electromagnet which is attached to the housing and through which a current flows, the amplitude of which is proportional to

gQ is nal to the load current. By means of a corresponding current transformer device with rectification, a field is generated by the electromagnet fixed to the housing, which repels the magnet on the actuating element until the switch is opened. If the design is chosen so that the first magnet closes a magnetic circuit by contact with essentially no air gap when the switch is closed, a snap-action switching characteristic is achieved. As soon as

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The electromagnet generates a field that allows the first magnet to lift off the magnetic circuit, so that an air gap is created/ the force of attraction in the magnetic circuit is suddenly reduced, whereby the force required to further repel the first magnet, which is achieved by magnetic repulsion, drops accordingly. This type of tripping concerns the pulse-shaped overcurrents that are to be protected, whereby the time course of the tripping process can be adjusted via the inertial masses of the actuating element to be moved.

For continuous overcurrent triggering, the magnetic field of the electromagnet or the current proportional to it is integrated via a suitable element, whereby the electrically excited magnetic field is then (abruptly) amplified when the integrated amount has reached a set limit. This can be achieved, for example, by an NTC resistor (resistor with negative temperature coefficient) through which a current proportional to the load current flows and which heats up until its transition temperature is reached and it abruptly reduces its resistance, thus allowing the current flow through the electromagnet to increase just as abruptly.

Preferably, the arrangement for holding the switch in the open position also comprises a (second) magnet which holds the first magnet in the open position of the switch. Since the present innovation does not provide any mechanical parts which have to carry out complicated movements, as is the case with the previous release mechanisms, the structure can be simplified and thus the costs for the safety device can be reduced. In particular , an automatic assembly is possible at least in sections due to the simple parts.

Further essential details of the present innovation emerge from the subclaims and the following description of preferred embodiments, which are explained below using figures - Here:

Fig. 1 is a schematic view of the mechanical

Structure of a preferred embodiment of the innovation;
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Fig. 2 is an electrical circuit diagram for the arrangement according to Fig. 1; and

Fig. 3 shows another preferred embodiment of the innovation in partial longitudinal section.

In the embodiment of the innovation shown in Fig. 1, the fuse comprises an actuating element 24 which is arranged so that it can move in a housing (not shown). At one end of the actuating element 24 there is a contact plate 15 which, depending on the position of the actuating element 24, bridges either two contacts 17, 17* fixed to the housing for the load current or two contacts 19, 19* also fixed to the housing for the emergency current. A (ring-shaped) magnet 28 is attached to the actuating element 24.

The actuating element 24 passes through the iron core 44 of a coil 25, the winding ends of which are connected to input terminals C and D of a control 20. Additional terminals A and B are connected to contacts 19 and 19*.

There is also a winding 26 on the iron core 44, which is connected to the input terminals E and E' of the fuse via the switch Sl (contacts 17, 17* and plate 15). This winding 26 has a very low resistance, generally a single or very few turns are sufficient.

-δ-A permanent magnet 32, also fixed to the housing, is arranged opposite the coil 25 on its core 44, the polarity of the magnets 32 and 28 being selected such that the two magnets are attracted to each other. Furthermore, the strength of the magnets 32 and 28 is selected such that when the magnet 28 is in contact with either the iron core 44 or the magnet 32, this contact remains due to the effective holding forces.

The controller 20 further has output lines connected to an illumination source 43.

The circuit of the innovation is described below using Fig. 2. The same reference numbers are used for identical or equivalent parts.

As can be seen from Fig. 2, the connection terminals D and C of the control 20 are connected via a diode Dl and a temperature-dependent resistor NTC with a negative temperature coefficient. Furthermore, a parallel circuit, consisting of a rechargeable battery Ba (lithium cell) and a Zener diode Z (whose Zener voltage corresponds to the charging voltage of the battery) is connected in series with a second diode D2, with this series circuit in turn being located between the connection terminals D and C of the control circuit 20. The diodes Dl and D2 as well as the Zener diode are always polarized in the same direction starting from the terminal D.

A series circuit consisting of the switch S2 (terminals A and B) and the lighting element 43 is connected in parallel to the battery Ba.

On the iron core 44 of the coil 25 sits the (one) winding 26, which is connected via the switch Sl to the input terminals E and E', so that when the switch Sl is switched on, the load current flows through the winding 26. This load

current through the winding 26 induces a current in the coil 25 which can only flow in one direction. This direction is determined by the diodes D1 and D2, with these diodes opening up two current paths: A first current path leads through the diode D1 and the downstream resistor NTC, with the amplitude of this current being determined by the size of the cold resistance of the NTC element. If the NTC element becomes hot because too much current is induced in the coil 25 via the winding 26 for a longer period of time, so that the heat generated in the NTC can no longer be sufficiently dissipated, the critical temperature of the NTC element is reached, whereupon it abruptly reduces its resistance. As soon as this much lower resistance is reached, a current which is higher than in the cold state flows through the coil 25, with the polarity of the diode D1 being selected such that this current leads to a magnetic field which repels the magnet 28. When the current flowing through the coil 25 reaches the corresponding amplitude, the magnet 28 is repelled and thus the switch S1 is opened.

In the state in which the switch Sl is still closed, the battery Ba is charged via the diode D2, with the charging voltage being stabilized via the Zener diode Z. However, the Zener diode Z not only serves to stabilize the charging voltage for the battery Ba, but also to enable an increased current flow through the coil 25 (in a single direction) when a peak in the load current occurs. If this peak is large enough to repel the magnet 28 accordingly or to lift it off the iron core 44, the actuating element 24 is lifted upwards (in Fig. 1) until the magnet 28 catches on the magnet 32 fixed to the housing. In this state, the switch Sl is open, but the switch S2 is closed, so that the battery Ba is coupled to the lighting source 43 and this lights up.

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Preferably, the illumination source 43 is located near

of the actuating element 24 or directly on it, so that the user can easily find it even in the dark when the safety device is triggered. 5

In the further preferred embodiment of the innovation shown in Fig. 3, the previously described parts are again provided with the same reference numbers. In this arrangement, the housing 10 is divided into three housing sections 11/12 and 13 which are fastened to one another, with the coil 25 being fastened with its magnetic core to the middle housing section. The contacts 17 and 17' are fastened in the lower housing section 13, from which a (standard) screw base 14 with the connections E and E ¹ protrudes. In addition, a compression spring 22 is supported in a hole in the lower housing section 13, which presses the actuating element 24 or 24* into the off position of the fuse.

The previously described contact plate 15 is attached to a lower section 24' of the actuating element by means of a screw 21 or the like, the contact bodies 16 and 18 of which interact with corresponding contact bodies on the contacts 17, 17* and 19, 19' and can thus close electrical circuits.

The lower section 24' of the actuating element is connected to an upper section 24, with the first magnet 28 being clamped at the connection point. This first magnet 28 consists of a magnet body 31 and two plate-shaped iron poles ?9 and 30.

The second magnet 32 comprises a total of three plate-shaped pole shoes 33, 34 and 35 with magnets 36 and 37 in between. The polarity of the magnets and the distances between the pole shoes are selected in such a way that ^the first magnet 28 can assume two different positions relative to the second magnet 32. In a lower position,

the upper pole plate 30 of the magnet 28, designated N, is located slightly below (in Fig. 3) the lowest pole plate 35, in the second position the lower pole plate 29 of the magnet 28 (designated S) is located near the middle pole plate 34 of the magnet 32, while the upper pole plate 30 of the lower magnet 28 is in the area of the uppermost pole plate 33 of the magnet 32.

An opening is provided in the upper housing section 11 through which a hollow pin 41 protrudes, which is seated on a holder 6 in which the upper magnet 32 is fixedly arranged. The hollow pin 41 has a bore 39 through which the upper end of the actuating element 24 can slide. In the outer housing section, the bore 39 is widened in such a way that even when the upper end of the actuating element 24 does not yet fully protrude from the hollow pin 41, this end is visible from the outside.

The holding element 38 is arranged in the upper housing section 11 so that it can move and is pushed upwards by a spring 27, which rests with its lower end on the middle section 12 of the housing 10. The section 38 also has a release pin 42 which protrudes through a hole in the upper housing section 11. The lighting element 43 is also provided on the upper section 11.

The control 20 (in the form of a printed circuit) is arranged between the middle housing section 12 and the lower housing section 13, whereby this arrangement as well as the electrical connections to the connection base 14 or to the lighting element 43 and to the coil 25 or the winding 26 do not represent any difficulty for the expert.

The position shown in Fig. 3 corresponds to the closed circuit, whereby the lower pole plate 29 of the magnet

ten 2&udiagr; sits firmly on the iron core 44 and is held by it. As soon as - as described above - a current flow is excited by the coil 25, the resulting magnetic field of which repels the magnet 28, the magnet 28 jumps together with the actuating element 24 upwards until its upper pole plate 30 is held in the area of the lowermost pole plate 35 of the magnet 32. At this point, the upper end of the actuating element 24 is visible within the recess 40. At the same time

The contacts 13 and 15 are connected via the plate 15 so that the lighting element 43 lights up. The user can now easily find the fuse and (after having previously eliminated the short circuit) press it back in. To do this, the user presses on the element 41 and thus pushes the magnet 32 and at the same time the magnet 28 downwards until the magnet 28 rests with its lowest pole plate 29 on the iron core 44. When it rests, the (holding) force between the core 44 and the magnet 28 increases abruptly so that the user can now let go of the element 41 again and the magnet 28 overcomes the holding force of the magnet 32. The position shown in Fig. 3 is now reached again.

To manually trigger the device, the user presses the pin 42 so that the bottom pole plate 35 of the magnet 32 rests on the iron core 44. At this moment, a magnetic orientation in the same direction as the magnet 28 is created in the core 44, so that the magnet 28 jumps up again. In this case, however, it jumps so far that its bottom pole plate 29 comes to rest in the area of the middle pole plate 34 of the upper magnet 32. If the user now lets go of the button 42, the holder 38 is pushed upwards by the spring 27. Even before the holder 38 hits the very top of the upper housing part 11, the actuating element 24 is held in place by a corresponding shoulder at its bottom end, which is connected to a section of the middle housing part 12 or to the con-

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central core section of the magnet core 44. The spring 27 presses the holder 38 further upwards until the previously described released position is reached again, in which the upper pole plate 30 of the magnet 28 is held in the area of the lowermost pole plate 35 of the magnet 32.

Claims (7)

Fuse for disconnecting a power cable when a permissible load current is exceeded, with a first switch which can be switched on manually via an actuating element which can be moved in a housing,
characterized in that electrical actuating means (25, 28) for opening the first switch (S1), a second switch (S2) on the actuating member (24) and an emergency lighting element (43) connected to the second switch (S2) for switching on are provided in the housing (10). 2. Fuse according to claim 1, characterized in that the electrical actuating means comprise a switch mounted on the actuating 4 ·
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t · · -2- organ (24) and an electromagnet (25) fastened to the housing (10), which is arranged opposite the first magnet (28) in such a way that the actuating organ (24) can be displaced by repulsive forces between the first magnet (28) and the electromagnet (25) to open the first switch (Sl). 3. Fuse according to one of the preceding claims, characterized in that magnetic means (44) are arranged on the housing (IJ) opposite the first magnet (28) in such a way that the first magnet (28) is held in place by the magnetic means (44) in the closed position of the first switch (Sl). 15 4. Fuse according to one of the preceding claims, characterized in that a second magnet (32) is arranged in the housing (10) opposite the first magnet (28) in such a way that the first magnet (28) is held by the second magnet (28) in the open position of the first switch (S1). 5. Fuse according to one of claims 2 to 4, characterized in that the electromagnet (25) is short-circuited via at least one diode (Dl, D2) and comprises an iron core (44) on which at least one winding (26) is seated to form a transformer, through which current can flow with connection terminals (E, E') of the fuse via the switch (Sl). 6. Fuse according to one of the preceding claims, characterized in that a rechargeable battery (Ba) is provided in the housing (10), which can be coupled to the lighting element (43) via the second switch (S2). -3- 7. Security according to claim 6, characterized, that the battery (Ba) is connected via a diode (D2) to a winding of the electromagnet (25). 30 I