DE1909085A1 - Electric switch - Google Patents

Description

Electrical Switch The ideal electrical switch has in the off state an infinitely large resistance and in the on-state no resistance.

During the switching process, the two states merge discontinuously0 The realization of the ideal switch is due to the given material properties and not possible because of the finite contact separation speed. Becomes an inductive Circuit switched off, so prepares the inevitable degradation in the consumer stored magnetic energy additional difficulties: the greater at the moment of switch-off the change in the switch resistance, the greater the voltages (overvoltages) are induced on the consumer, causing an arc flashover on the switch contacts has the consequence. Is an inductive circuit fed with alternating current in the current zero crossing switched off, then suddenly the one existing at the power source at that moment occurs Voltage at the switch contacts on (recurring voltage), which also leads to a It leads to arcing.

The main difficulty of switch technology lies in mastering it of the arc, the one with increasing cut-off voltages and cut-off currents becomes correspondingly more energetic.

The object of the invention is to avoid this arc.

Detected in the event of an auxiliary shutdown, from the beginning of the contact separation until the final shutdown, the time curve of the arc voltage and of the arc current, the curve of the arc resistance can be determined for this period calculate. If you now use a instead of the well-known (arc) switch Switch in which the change in the contact resistance over time in the the same sense takes place and in which the current load capacity and the dielectric strength of the variable switch contact resistance is sufficient at all times is, then a completely arc-free shutdown can be achieved in this way. In contrast to the usual switch, where because of the (in the last phase of the Contact separation) only punctually Making contact, the one to be destroyed Energy (arc losses) on a very small amount of material (metal and air) is concentrated, which causes a very high temperature (up to 10,000 degrees C) and thus material migration. and deformation results, the resistance switch is the one to be destroyed Transferring energy to a relatively large volume of material, which is only a relative low heating and therefore no material deformation with it.

Switches have already been specified for which the volume resistance smaller during the switch-on process and larger during the switch-off process (Ründennberg: Electrical switching operations 1953 page 12 and Nesselring: Theoretical Basics for calculating switching devices, Sanzmlung Göschen 1968, page 183). The change in resistance takes place here with the aid of a sliding resistor and an electrodynamic drive. The disadvantage of this arrangement reads in the less secure and gradual contact, the large contact support, the low contact speed and in relative terms, the invention brings about an advantageous improvement in the case of an electrical switch, in which the volume resistance during the switch-on process becomes smaller and larger during the switch-off process and is characterized by that the contact surface roll on each other during the switching process. To this In this way, the force required, including contact wear, is significantly reduced. The contacts are made of gold and / or silver or to ensure reliable contact from an alloy of these i; et, lle. The use of gold is possible here, there as a result of the arc-free shutdown, excessive heating is avoided.

In order to be able to do so in the final phase d. b. Shutdown process, d. H. at this moment, where the counter-contact separates from gas flow, a light arc or spark formation, To avoid this, a relatively large total resistance is required (e.g. 9 km-Ohm at 220 V AC). In the further embodiment of the invention, the iidersta-ndsdrait, the partial surface of which forms the contact area, wholly or partially in thin and / or obliquely applied to its base (thin film technique ). In this way, a relatively large total resistance is achieved in a very small space. E.g. a 1 cm long gold layer with a cross section of 10-6 sqmm has a resistance from 230 #.

When determining the wire cross-section, the different load must be taken into account in the individual switching phases. This results in, that the cross-section of the resistance wire emanating from the main contact is continuous can decrease.

With this, the contact surfaces from the effects of the weather and impurities (e.g. 3rd dust) are spared, the same, as with the well-known reed contact switch, housed in a closed vessel (e.g. made of glass). The vessel can, for example Illit be filled with protective gas. However, it is more expedient to evacuate the vessel. In this way, in conjunction with the complete freedom from arcing given here the advantages of the real vacuum switch - in contrast to the known (arc) Vacuum switch - guaranteed for an almost unlimited time. These are: The contact distance can be about 10 times less than in air, because the dielectric strength of the high vacuum is correspondingly higher. The smaller contact distance enables a shorter one Switching time (contact movement time). In addition, the lack of air resistance the contact speed increases. Furthermore, the contact surfaces remain chemically clean, so that safe contact is always guaranteed.

To achieve the lowest possible volume resistance when switched on State, it is appropriate the main contacts including the connections made of silver and to gild the touching contact surfaces. To the contact pieces or to be able to magnetically influence their magnetic carriers, the same exist Additionally made of layers with magnetic material (e.g. iron, nickel).

So that the contact surfaces can roll on each other, at least -eille must be used the same be curved in the rolling direction. The contact surfaces of the known Reed contact switches are made of a very hard material (Ni-Fe). Therefore finds with the low contact pressures present here (20 - 50 p) only one contact is made iii a few points. The effective contact area is extremely small. The consequence is a relatively high one Contact resistance (15 - 200 m #). the use of the relatively soft gold proposed here is guaranteed a much larger area of contact with the contact surfaces. To you as much as possible To achieve complete surface contact, at least one of the contact surfaces designed as a film, under which there is an air cushion or an enclosed one Mercury volume is located. In this way, the contact interface becomes Opposite contact surface arched and elastic.

To avoid amalgation there is e.g. between the gold foil and the mercury underneath, an intermediate layer of iron or nickel. The contact can also be increased in a manner known per se in that the contact surfaces receive a mercury film.

The three proposed measures also reduce contact bruise largely prevented. If, despite the measures mentioned, contact bruises are still present occur, then this does not result in arcing in the switch according to the invention, because because of the rolling of the contact, the contact bruises only affect parts of the resistance track can extend and therefore a complete contact separation in the course of the switching process is excluded.

In the known reed contact switches, the soft magnetic Tongues used simultaneously to conduct electricity. Because these tongues are made of nickel-iron exist, they have a relatively high electrical resistance; he lies six times as high as silver. To lower the switch resistance in full When switched on, the two main contacts are fixed;, and the closing the same takes place via a moving contact bridge.

The movement of the contact bridge or the contact bridge support can be done by mechanical, magnetic or electrical forces. At mec, lanisc: ler Movement, e.g. by manually operating a switch button, is the use of a Spring required, so that one is sufficient even with slow hand movements short contact movement time achieved and thus the current overload of the resistance track is avoided. The movement of the switch contact by electrical forces can e.g. with the aid of a piezoelectric 3-way oscillator (according to G. Arlt, Fa.

Philips).

In order to keep the energy consumption required for the switching process as low as possible to keep and to increase the service life of the contact carrier, is in the further Embodiment of the invention the movable contact piece at no point mechanically attached and the leadership of the same by magnetic fields and / or mechanical Limitations accomplished. So that the flying contact bridge during the switching process always hits the intended surface and cannot deviate from it both in flight contact and in fixed contact, the magnetic fields Inhomogeneous design, e.g. due to sharp opposing magnetic edges.

In order to have the largest possible contact rolling surface in the event of a loose contact to achieve, the loose contact can lie on a curved contact surface and the switching process is done by lips.

The loose contact bridge carrier consists of an elongated metal, which is magnetically soft in the middle and a permanent magnet at each end owns. By reversing the polarity of the magnetic forces acting on the outside magnets a single rocking of the contact bridge carrier and thus a ring respectively.

Switching off causes.

In the case of the known reed contact switches, the contact tongues are touched only from a certain induction or excitation (response excitation). The magnetic wounds but experience a relatively large approximation even before the response stimulus is reached. This fact has an unfavorable effect on the construction of the reed contact switch off, in particular the contact distance must be due to the permissible dielectric strength be enlarged accordingly. In the further development of the winding are to avoid this disadvantage, when switching to the moving parts forces acting against the direction of movement and repelling in the direction of movement attractive. In this way not only become unambiguous and independent of the excitement Switching states achieved. In addition, higher contact speeds and a higher resistance to shaking achieved.

So that when the contact bridge carrier is lipped, the same on its base can exert a pressure for secure contact is opposite to the soft magnetic Middle part of the i: ontakt bridge girder on the base a permanent magnet.

The magnet reversal can be done in a number of ways, e.g.

by electromagnets, in which the polarity of the supply voltage is changed. If the switch is used as a residual current circuit breaker, then however, if a fault current flows, a shutdown would not be guaranteed, if the mains voltage falls below a certain value. For these reasons and To simplify the circuit, it is advisable to use a permanent magnet use. In the further embodiment of the invention leads to an electrical or permanent magnet of everyone; Pole each one plastic leg to a common one Tongue and thereby counter-excitation or magnetic flux blocking (blocking magnet principle) of the one or the other leg becomes one or the other pole type on the tongue brought into effect.

The rolling of one contact surface on the other can thereby happen that a flexible flat metal band is more and more curved to a curved one Surface is sloping. After completion of the switch-on movement, both then touch Contact surfaces completely. A rigid piece of metal is used as the contact carrier and the switching movement triggered by a rocker action, then has in each eye only a certain part of the contact surfaces touch.

In the further embodiment of the invention, the contact bridge is designed as a ball or roller, which to. reil made of soft magnetic material consists. The rolling contact bridge becomes linear through a linear raagnetic one Moving field or in a circular or circular spiral shape by a rotating magnetic field. Due to the spiral-shaped path, the rolling contact piece can be moved with the help of a single Rotating field of several travel movements and thus a relatively long resistance path run through. The ball or roller rolls in a semicircular channel in the the resistance tracks are located. In the in state, the two main contacts bridged directly. Veit1 Sin state rolling to the off state bridges the ball or, roll an ever larger '¢ iderstana. With the rotary field switch the ball or the roller by: the centrifugal force pressed against the resistance tracks. Since the ball or roller is not braked immediately when the end state is reached can be, a certain run-out must be available. In order to the ball or roller to the Gegenkontaktflä large area can nestle, it has the following concentric layers (from outside to inside): Gold, silver, nickel iron, mercury, nickel iron, air. The frequency of the voltage with which the three-phase windings are fed, can be used to generate an optimal Switching process can be influenced by the sizes of the Netzzstandes.

It is well known that electrically or magnetically controllable semiconductors can be used can also be used as electrical switches. With most types of semiconductors (e.g. transistor, MOS-FET, field plates, magnetic diode) is the contact resistance in the on-state relatively large and also dependent on the level of the tax variable.

In heavy current engineering, these switches are therefore not or only applicable in special cases. However, there is a certain application of this switch Dimensions possible if they are to a reed contact switch or to the switch according to the invention can be connected in parallel. The one that occurs on the semiconductor when it is switched on The voltage drop is relatively small, so that the mechanical switch is only one has to switch on low voltage.

When switching off, first the mechanical and then the electronic Switch to be turned off. In the case of a magnetically influenceable semiconductor (e.g. Field plate or magnetic diode) can have the magnetic influence of moving Contact carrier take place.

With the current state of the art, the necessary requirements to the semiconductor (e.g. high switching voltage, high current carrying capacity, high resistance in the off-state and low resistance in the on-state) from the thyristor to the greatest extent Fulfills. When connecting a thyristor in parallel with a reed contact switch or with the switch according to the invention, the mechanical switch only needs more to switch a voltage i of the order of magnitude of 1.5 V on or off. In contrast for the known parallel connection of a thyristor with a high-voltage contactor here an almost inertia-free and timely switching movement is possible, so that the Thyristor is hardly loaded and therefore the otherwise necessary cooling systems are not required.

When combining an overcurrent and short-circuit switch with a fault current circuit breaker must be used at the same time Appear of overflow and fault currents, one caused by the interaction of the two currents Shutdown can be avoided if both currents are below their nominal values. In the further embodiment of the invention, this is done with the aid of what is known per se Blocking magnets avoided in the following way: The switch is triggered when a fault current occurs in a manner known per se in that all Lead the lines leading to the consumer through a window in the magnet leg and the magnetic flux is blocked by the magnetic field generated by the total current. At another point of the soft magnetic leg and outside the area of influence This window, the magnet leg is widened and also has a Window. Only one lead wire leads through this window.

In the event of a short circuit, it causes an instant shutdown, also through magnetic lock. The greater the thigh spread, the greater must be the short-circuit current leading to the shutdown. For overcurrent shutdown this arrangement cannot be used, since overcurrent protection has a temporal effect delayed shutdown is required. In order to obtain a depending on the size of the overcurrent, To achieve a time-delayed shutdown CLOSE is located on the smaller arm of the short-circuit window a coil. An external or / and self-regulating coil is attached to this coil Resistance, preferably a measuring conductor connected. The one connecting line leads through a further area of flow that is not in the flow area of the other windows ßcnster, that siC: also crazy; soft magnetic leg is located. The vo Lberstrom Voltage transformed into the coil heats up the scissor conductor after a certain period of time on. The lead resistance becomes lower and the current flowing through it is correspondingly lower larger: This current blocks the permanent magnetic flux due to its magnetic field in the overcurrent window and the switch turns off. By inserting a rheostat in this circuit the tripping overcurrent can be made controllable.

The practice time, d &? just like with high-voltage systems In the case of low-voltage systems, many malfunctions only occur for a short time and therefore an automatic restart would also be advantageous here. Whether to the realization This measure does not reactivate the system until the fault has disappeared or whether they occur after a fixed time delay, with a final one Shutdown takes place when the fault is still in effect (similar to the known "Short interruption" in high-voltage systems) is a fundamental question. Technically the first eg regarding fault current and short circuit current would be realizable while the overcurrent shutdown due to the different consumer resistances at Switching on and causing insurmountable difficulties in operation. However, for reasons of people and facts, the question must be clearly in favor of the second 5WaJeges are answered. The following, in practice, serve as a justification Possible situation: If there is a permanent malfunction and the installer forgets switch off the system with the manual switch before remedying the problem the system at the moment the fault is rectified (e.g. if it is opened with an Power socket at the connection terminals a dirt bridge removed) voltage again. At this moment, the installer can touch a live point have and have an accident. It can also be due to the sudden and unprepared If the system is restarted, mechanical damage occurs.

Regarding the period after which the automatic restart should take place, the following is to be considered: the interruption time must not be be short, because most disorders take a certain amount of time to go away. However, the interruption time must not be too long either. It is allowed for the system user In no case do you get the impression that the system is permanently switched off. This erroneous assumption could be made when troubleshooting is started immediately lead to an accident.

An interruption time of 0.2 to 1 sec should be appropriate, the lower values primarily for interruption-sensitive systems (certain manufacturing plants) come into question.

The realization of the automatic reclosing is for example possible as follows: between the fault protection switch and the consumer Charged by two rectifiers, two Yon capacitors. Switches the circuit breaker in pole of a fault off, the charging current is interrupted. It only one of the two capacitors gets rid of, as there is only a discharge resistor in parallel with iJlm is switched. After a certain time, the size of the charging resistor depends, exceeds the increasing differential voltage of the two in series switched capacitors the switching voltage of the four-layer diode connected in between. The capacitor discharge current now causes the system to be switched on again. Is the There was still a fault when switching on again, then a final one takes place Shutdown because the capacitors do not charge during the interruption time could.

In the drawing are exemplary embodiments of the inventive concept shown. In lig. 1 shows the switch according to the invention in principle (here side view). The resistance path is created by the wavy line running from 2 to 3 indicated.

It consists of a thin and narrow gold foil and is on one curved insulating pad applied in a meandering shape. Becomes a force on the pliable Switch tongue 1, which also has a gold layer on its underside, exercised, then the first contact takes place at the free end of the resistance track 3. The more the contact tongue is pressed down, the more it rolls over it resistance track, the lower the switch's volume resistance becomes. On the covenant During the switching movement, the contact tongue touches point 2 and the switch is now fully switched on.

The switch can also be designed as a bypass switch a, us, -; e. At the point 2 in Fig. 1, the two connection contacts are located next to one another in an isolated manner. A top view of these two contacts with the adjoining resistor tracks is shown in FIG. The two contacts 5 and their resistance tracks are in the off state isolated from each other. When switching on, the two resistance tracks are with the gold-plated underside of the contact tongue is first bridged at point 4. At the At the end of the switching process, the two Kauptkontakte 5 are through the at the end of the Contact tongue lying bridging contact, which is made of a thicker silver layer r: it consists of gold plating, bridged.

In Fig. 3, the switching process is triggered by manual operation. the Force is exerted on a spring at point 6, one end of which is attached to the point 10 is attached. After a certain stroke, the intermediate spring jumps over 7 the contact spring 8 suddenly approaches the resistance track 9 and covers the same, starting from the right completely. With the help of the spring 7 it is known per se Way ensures quick contact even with slow hand movements and thus a current overload of the thin resistance tracks is avoided.

In Fi £. 4 the switching process is carried out by an electrically generated megnetic Force triggered. The two switch connections 11 and 12 are isolated from one another through the glass vessel 13 and end in the two main contacts (the top view of these Main contacts together with their resistance tracks arises from Fig. 2).

They are surrounded by a soft magnetic iron in an electrically insulated manner the -nach ai '!? en (14) and right back into the glass vessel and on one elastic contact tongue 15 ends. Is attached to the outer leg 14 wound coil 16 applied an electrical voltage, then the contact tongue 15 magnetically attached to the iron located at the main contacts The switch-on process takes place in the already mentioned silane.

In Figure 5, a switch is shown in cross section, in which a completely loose contact bridge flies towards the main contacts during the switching process. The flying bridge piece 17 is a permanent magnet. At the bottom is the Konbrücke made of silver with gold surface 18. This contact bridge was previously adhered in the off position on the upper magnet legs 19 and 20. By the switch-on current the magnetic poles were polarized so that the permanent magnet piece 17 (is at the same time flying Contact bridge) repelled by poles 19 and 20 and attracted by poles 21 and 22 became. At the end of the flight, the contact bridge 18 bridges the two main contacts 23 and 24.

After the switching process has been completed, the permanent magnet 17 also remains then on the stools 21 and 22 (and also with the anode ren switching status at the legs 19 and 20) adhere when the magnetism Iser Scenel is canceled, The main contacts 23 and 24, together with their leads, are from the magnet legs electric isolated.

so that the flight contact 18 is exactly the right one for each switching movement Point flies are on the outsides executed for flight contact 18 the magnetic leg surfaces and just as aril flight contact even sharp edges 25, through which an increased magnetic field is generated.

You can get one with the main contacts underneath the gold-silver layer arrange a volume of mercury surrounded by an iron layer. The contact surface if this increases the putty somewhat, the total surface of a contact is preserved such a weak circular pyramid shape. This way, complete surface contact is achieved achieved. When locking in, the first contact is made with the middle of the Lonta'-t, with The last $ touch occurs when the contact is in the middle of the switch. During the switching process the contact area increases or decreases in a circular manner. So are too Here the conditions for a resistance switch are given, if one of the Contact center off; on an insulating surface the resistance tracks are spiral-shaped brings up.

In Fig. 6, a contact bridge that is not attached is also indicated. Here the switching process takes place by means of a rocker movement.

The contact bridge 26 is here on the way from the off state in the on-state. In the off state, the left Daermagnet 27 adhered to the magnet legs 28 and the right permanent magnet 29 on the magnet legs 32. By reversing the polarity of the magnet The types of poles indicated in FIG. 6 were created in the magnet legs 19, 20, 21 and 22. The result is that the permanent magnet 27 is disconnected from the leg 28 and from the leg 31 is tightened. Likewise, the permanent magnet 29 is repelled by the leg 32 and attracted by leg 30. Since the middle part of the contact bridge 26 is made of soft magnetic, Material is and under the resistance track 33 is a permanent magnet, sticks the contact bridge during the entire rocker movement on its base, so that always a safe contact is given. During the switch-on process, these travel the -: resistance tracks 33 in the direction of the main contacts 34 and 35 continuously bridged.

, n Fig. 7 is a magnetic switch shown, which with the help of the well-known blocking magnet (DP 911755) works. To the Polish ends of the permanent magnet 36 are two soft magnetic legs 37 and 38, as well as per pole 39 and 40 attached. The mutually opposing legs 37 and 39 and also 38 and 40 are also crossed by additional soft magnetic ones Legs 41 and 42 or 43 and 44 connected. In this state are at the leg ends 37, 38, 39 and 40 no magnetic forces are effective because the magnetic fluxes of the permanent magnet via the transverse legs 41, 42, 4) 7 and 44 can flow.

However, there are windows and will in the individual legs certain windows penetrated by a current-carrying conductor, the Ends of the legs 37, 38, 39 and 40 to magnetic poles and influence the Permanent magnets 45 (= contacts bridge) so that it is up or depending on the polarity moved down. The following conditions arise in detail: ITjaftet der Permanent magnet 45 on the lower magnet legs 39 and 40 (= B'in-position) and are windows 46, 47, 48 and 49 are penetrated by a conductor that suddenly carries the current is flowed through, the magnetic fluxes are blocked in the legs concerned. Because of these blockages, on the other hand, the magnetic fluxes can flow through the legs 43 and 44, as well as 37 and 39 develop unhindered. This condition has the consequence that the leg ends 37 and 40 to the north and the leg ends 38 and 39 to South Poland will be. The consequence of these magnetic conditions is that dat; the permanent magnet 45 (= contact bridge) repelled from the leg ends 39 and 40 and from the leg ends 37 and 38 is tightened. So it moves up to the off position. Will after switching off the off current, a current through the on windows 50, 51, 52 and 53 then the polarity of the four leg ends is reversed compared to the previous polarity and the permanent magnet 45 moves back down to the on position.

Both for the binary switching as well as for the aws switching are here own control lines required. The control current must flow at least as long as until the permanent magnet 45 has covered half of its way. When using the switch according to the invention, this condition is also met if the cause of the Breaking current (fault, overcurrent or short-circuit current) through the switch itself is switched off. This is the case because the control current, albeit weaker becoming, almost flows during the entire switching process. A Holding current is not required in the on or off position, because in these states the permanent magnet 45 on the soft magnetic leg ends, which is now used by others Magnetic fields are not influenced, adheres.

8 shows the parallel connection of the switch according to the invention (indicated by 54) with a transistor ir ¢ 1 principle as given. will the If the manual switch 56 is switched on, the transistor 55 switches first and then the transistor 55 Switch 54 switches the load resistor 57 on, the wall switch is switched off again, so first the switch 54 and then the transistor 55 turns off. In this way the switch 54 only needs to cope with a relatively low voltage. ILI individual the switching processes proceed as follows: After switching on the manual switch 56 receives the transistor 55 via the transformer 58 and the bridge rectifier 59 a control voltage and the collector-emitter path is switched through in every direction of current. At the same time the coil t receives voltage and that as a result resulting magnetic reld closes (due to the mechanical inertia after the 'transistor through-connection) the switch 54.

Besides the transistor 55 and the coil 6G, the capacitors are also used 61 and 62 fed with equal voltage and thereby charged. The capacitor 61 is necessary so that the switch 54 does not switch off at each current zero crossing. The rectifier 63 is to prevent the discharge of de Kennensators 62 over the coil 60 is necessary.

If the manual switch 56 is switched off again, the Load resistor 57 switched off in the following way: Since the condenser 61 has a relatively small capacity, the coil 60 is energized first withdrawn. The voltage induced in the coil by the breakdown of the magnetic cell is discharged via the freewheeling diode 64 so that other components are not disturbed can be. Since the excitation coil 60 no longer has any voltage, the switch switches 54 from. The capacitor 62 is dimensioned so that it still has voltage. He gives control voltage to the transistor for a short time until it disappears when the same finally switches off.

In Sig. 9, the parallel circuit of the switch according to the invention is age with two thyristors 66 and 67 connected in opposite directions in principle. The control grids of the two thyristors are each with a resistance track of the two Contacts of the mechanical switch, namely at 68 and 69 connected. The consumer resistance 70 is turned on in the following way: When the Meclian switch is turned on the resistance of the two resistance tracks is getting smaller and smaller. Depending on the direction of the current One or the other thyristor is triggered when the mains voltage is present and switched through when the ignition voltage has reached the required value. egg the mechanical switch needs the further bridging of the resistance tracks only switch on about 1.5 V. Once the mechanical switching process has ended, i.e. when the two main contacts are bridged, the flow of current through the stops Thyristor on because the anode voltage has now almost disappeared. When switching on So the thyristor will only be loaded for a short time. Of course, it also flows during no current through the thyristor during operation. When switching off, one of the thyristors will ignited shortly after the start of the switching movement. Need for the further switching movement therefore only about 1.5 V are switched off. The current flow through the thyristor lasts until the next current zero crossing.

The contact movement time depends to a certain extent on the @@@@ the supply voltage addicted. Instead of the two thyristors, a triac can also be used; the common grid must for galvanic separation of each resistance track over each a rectifier can be connected.

In Fig. 10, the leg of a locking magnet is shown, at the independent of each other fault and overcurrent a solenoid lock and thus a Can cause shutdown. The soft magnetic emanating from each pole (here the north pole) Leg has three windows 71, 72 and 73. All consumer feed lines lead through window 71. If a fault current to earth occurs (inclusion) in the consumer system, then it causes the resulting total current causes a solenoid lock, resulting in a shutdown Consequence. Each individual lead wire also leads through a further window. Kier is just one such window 72 for a lead wire 75 drawn. Because of the widening of the thigh at this point, the normal Operating current do not yet cause a magnet lock, only a short-circuit current. A coil is wound around the narrower leg of the window 72. There is a NTC thermistor 74 connected. A connecting wire leads through the window 73. The Operating current flowing through conductor 75 is induced in the coil of the window 72 a tension. This voltage is too small and therefore has no particular effect. However, if an overcurrent occurs, the coil voltage increases, the NTC thermistor 74 becomes poorer and diminished with a time delay due to the current flowing through it thereby his resistance. The coil current, which increases as a result, blocks in the window 73 the magnetic flux, which triggers the shutdown of the consumer. The lower the overcurrent is, the more time it takes to switch off, the higher the overcurrent the faster the shutdown takes place. With the help of one in series with the thermistor switched rheostat, the overcurrent release value can be set by hand.

In Fig. 11 the circuit of a circuit breaker (here two-pole) In principle again: the consumer in the event of fault current, overcurrent or short circuit 76 switched off (fault circuit breaker), at deI, after a certain time a automatic restart takes place and then switches off finally when the fault is still present. The consumer 76 is via the switching contacts 77 and 73 connected to the power source 79. The two capacitors 80 and 81 are has been charged via the rectifiers 82 and 83 and via the resistors 84 and 85. The capacitor 80 is charged to the peak value of the mains voltage. The voltage on the other hand, at the capacitor 81 it fluctuates constantly slightly below the network peak voltage, because during a larger part of each network wave there is a discharge through the resistor 86 takes place. However, this resistance is so great that in the presence of the mains voltage the difference between the two capacitor voltages remains much smaller than the switching voltage the four layer diode 87.

If a fault current of sufficient magnitude flows through the earth fault resistance 88 to earth, a total magnetic field is created around the leads 89 and 90, that the switching contacts on the above-mentioned way to Shutdown brings. This Sunlmenfeld is z ß. effective when the two lines 89 and 90 lead through the out window of the blocking magnet according to FIG. In the above The manner described (FIG. 10) is also switched off in the event of an overcurrent or Short circuit. The shutdown from the network has the consequence that the capacitor 81 is discharges more and more via the resistor 86 without an iTacll charge through the network can be done. After a certain time (Z .. 0.5 s) it is discharged so far that the Differential voltage of the series-connected capacitors 80 and 81 is the switching voltage of the four-layer diode 87 reached. The result is sudden and extensive Discharge of the capacitors. The discharge current flows with the help of the connecting line 91 through the on-window of the blocking magnet according to FIG. 7 and switches in this way the fault circuit breaker on again. In the meantime, is the cause of the malfunction disappeared, the switch remains on; if the fault is still present, then it is switched off again immediately. Another automatic switch-on can no longer be done now, since in the meantime the capacitors 80 and 81 not charged.

Switching on by hand is possible by briefly pressing the double-pole Pushbutton switch 92 possible. This activates the capacitor after a short command time recharged.

When the switching voltage of the four-light diode 87 is reached, it switches the circuit breaker switches on again and remains switched on if there is no fault is.

The switching off of the circuit breaker by hand is through the push button switch 93 possible. As a result, the capacitor 80 is discharged through the resistor 94. Of the Discharge current causes a magnet lock in window 71 of FIG. 10 and thus the Switching off the consumer resistor 76. An automatic restart can no longer take place because the capacitor 30 is discharged.

Claims (25)

P a t e n t a n s p r ü c h e 1. Electrical 'switch, in which the i> urchgaii £ "swiderstaifd smaller during the switch-on process and larger during the switch-off process is, characterized in that the contact surfaces during the switching process roll over each other. 2. Switch according to claim 1, characterized in that? the contact surfaces consist of gold and / or silver. 3. Switch according to claim 1 or 2, characterized in that the Resistance wire, the partial surface of which forms the contact surface, whole or is partially applied in thin or / or narrow strips on its base. 4. Switch according to claim 1 to 3, characterized in that the Contacts in a closed, evacuated or inert gas-filled vessel, preferably made of glass. 5. Switch according to claim 1 to 4, characterized in that all or a part of the current-carrying contacts made of several layers of different metal consist, preferably of gold, bases, nickel and / or silver. 6. Switch according to claim 1 to 5, characterized in that all or some of the contact surfaces consist of metal foils, which through a volume of gas or mercury below it towards the counter contact surface are arched and elastic. 7. Switch according to claim 1 to 6, characterized in that the the two contacts are fixed and the wear and tear of the same via a movable one Koiitaktbrücke takes place. 8. Switch according to claim 1 to 7, characterized in that the Switching movement by inechanical forces, preferably with the help of a spring (7) takes place. 9. Switch according to claim 1 to 8, characterized in that the Switching movement takes place through magnetic forces. 10. Switch according to claim 1 to 8, characterized in that the Switching movement by electrical forces, preferably with the aid of a piezoelectric Flexural oscillator takes place. 11. Switch, in particular according to one or more of the preceding Claims, characterized in that the movable contact piece at no point is mechanically attached and the leadership of the same by magnetic fields and / or mechanical limitations takes place. 12. Switch according to claim 11, characterized in that the movable and mechanically not fastened contact piece in the middle made of magnetically soft material (26) and consist of a permanent magnet (27, 29) on each of the two ends. 13. Switch according to claim 12, characterized in that the soft magnetic Central part of the movable contact piece, opposite fixed part of the switch (33) consists of a permanent magnet. 14. Switch to one; or more of the preceding claims, characterized in that the change in the switching state by reversing the polarity the permanent magnets of the movable contact piece (26) acting magnetic Forces is caused. 15. Switch according to claim 14, characterized in that the on forces acting on the movable contact piece (17) counter to the direction of movement repel and are attractive in the direction of movement. 16. Magnetic switch, especially for a switch after a or more of the preceding claims, characterized in that in one Electro or acid magnets from each pole a soft magnetic leg to one common tongue leads and by counter-excitation or magnetic flow blocking of the one or the other leg the one or the other pole type on the tongue to the effect is brought. 17. Switch according to one or more of the preceding claims, characterized in that the contact bridge is spherical or cylindrical and for Part is made of soft magnetic material. 18. Switch according to claim 17, characterized in that the rolling Contact bridge through a linear or circular moving magnetic field (rotating field) is moved, which is, for example, ore fflted by three-phase windings. 19. Switch according to one or more of the preceding claims, characterized in that after the on-state has been reached, an additional Switch with a large contact area is connected in parallel, for example through a magnetic proximity switch as a result of the approach of the shawl ball or roller and that when switching off at the beginning of the switching off process, the additional switch is switched off again. 20. Switch according to claim 18 or 19, characterized in that the frequency of the voltage with which the three-phase windings are fed is variable is and is influenced in the sense of an optimal elimination. 21. @eedcontact switch, especially after one or more of the preceding claims, characterized in that a parallel to the switch semiconductors that can be influenced electrically or magnetically (e.g. transistor, thyristor, MOS-FET, field plate, magnetic diode) and is temporally influenced so that the Switching on the semiconductors before the switch and when switching off the switch before is switched to the conductor. 22. Switch according to claim 21, characterized in that the magnetic influence of the semiconductor by the movement of the magnetic contact piece carrier he follows. 23. Switch according to one or more of the preceding claims, characterized in that the soft magnetic leg is the magnetic switch has a widening with a window located therein and through this Window (72) only one sales line is routed. 24. Switch according to claim 23, characterized in that the through the window (72) resulting lifting leg carries a coil that is and / or a self-adjustable resistor, preferably a chisel conductor (74), a circuit forms, which moves through its own window (73), which is not in the area of influence of a other window. 25. Switch, in particular according to one or more of the preceding Claims, characterized in that between the switch (77, 78) and the consumer (76) two capacitors (80, 81) are charged via two rectifiers (82, 83) and if there is no mains voltage a discharge a capacitor as a result of a parallel resistor (86) takes place and the resulting increasing differential voltage both capacitors, for example with the help of a voltage-dependent resistor (87) is used for reclosing,