DE4340632A1 - Electrical switching device - Google Patents

Description

The invention relates to an electrical switching device according to the preamble of claim 1.

Switching devices with which, in particular, on average voltage and high voltage range overcurrents, preferred wise short-circuit currents, are switched off as Circuit breaker trained, e.g. B. for high voltage as SF₆ circuit breakers or for medium voltage as vacuum switches or low-oil switches as well as SF₆- Circuit breaker.

The object of the invention is to provide a switching device to create the type mentioned at the same time Switching power is cheaper to produce.

This object is achieved by the kenn Drawing features of claim 1.  

The invention takes advantage of certain materia lien and certain compositions of materials, for example those described in patent application P 42 21 309 are described with increasing current their tempera tur and thus increase their resistance. One switches such a non-linear resistor in series with ei switchgear, then when a short occurs final current or in general an overcurrent Current limited so that the prospective short circuit or Overcurrent is not reached. This has the consequence that a specially designed for short-circuit shutdowns Circuit breakers do not have to be used, but that a disconnector or switch disconnector can be used, who only needs to be able to determine the remainder or denomination switch off electricity in a certain time. The use of egg such non-linear resistance in connection with such a disconnector or switch disconnector leads to egg a significant reduction in the cost of a short final switching device. The disconnect or load disconnect scarf ter can be used as a quick disconnect switch for certain purposes be designed; it’s also possible, if the non-linear resistance behaves the voltage can hold a reasonably long time, an inexpensive order not to say cheap, slow disconnector, on put in the off position only the voltage is able to hold.

A particularly advantageous way of using egg Such a non-linear resistor consists of that he according to claim 3 with means for detecting the Än change in the properties of the resistance at the beach Which means can be used in the network conductor a signal when the certain overcurrent occurs testify that an actuator for the separating or switch disconnector is supplied.  

One takes advantage of the fact that when the overcurrent occurs certain properties of the change non-linear resistance. For one thing changes the tension to be tapped on him, since the not li neare resistance increases its resistance value; these Voltage changes can be detected and processed.

The non-linear resistance changes when a occurs Overcurrent and increasing the temperature to its other geometric dimensions; the change in dimensions, in particular the change in volume or length can do this be used to effect a shutdown.

Of course, a temperature measuring element can also be used be attached to the resistor; increasing the tempe rature then generates the relevant signal.

An advantageous embodiment of the invention can be according to Claim 2 to go there that the non-linear resistance an impedance is connected in parallel. This impedance can linear or non-linear, i.e. H. voltage-dependent. It can be designed as a capacitor that is based on can be charged to reduce voltage peaks. Instead of egg A capacitor can also be provided his. The impedance can match the nonlinear resistance be integrated or discrete. Wherever the magne Small inductance in the network and therefore that in the network stored energy is low, is the parallel scarf Impedance is not required. Where, however, high There are no inductors in the network linear resistance these impedances are connected in parallel become.

Furthermore, according to claim 7 in parallel with the resistor an actuator, e.g. B. in the form of a piezo element, ge be switched on when the increased voltage occurs  falling on the resistor with this voltage and thereby also a change in length or an off bend experiences. This change in length or deflection can then to actuate the actuator Switch-off switch disconnection can be used.

A particularly advantageous embodiment of the invention can go according to claim 8 that the non-linear Resistor or resistance element is a switching mechanism is associated with a latching point, which the Switching device actuated. According to An Say 9 assigned a sliding element to the switching mechanism be net, which is preferably as a pin or Sleeve is formed and the actuator for controls the switch or actuates the switch directly. The non-linear resistor can be according to claim 10 or 11 of course also an electromagnetic trigger be arranged, which operates the switching mechanism, d. H. unlatched.

It can be connected to an electrode of the non-linear counter a conductor must be connected, which is part of the electromagnetic trigger.

In a particularly advantageous manner, according to claim 13 the non-linear resistance with the switching mechanism and / or the trigger and / or the conductor and / or the Locking by a support arrangement made of insulating Material held together; the carrier arrangement can formed according to one of claims 14 and 15 be or according to claim 16 a sleeve of insulating Include material that at least the non-linear Wi the state encloses, the non-linear resistance can be directly sealed by the envelope and the trigger and / or switching mechanism in a free Interior of the sleeve are housed.  

The sleeve can be tubular, preferably be cylindrical and cover at its ends have caps on which an electrical connection or disconnection leadership is connected.

The insulating material can be used in a particularly preferred manner Material for the carrier arrangement, in particular the cover a material with preferably voltage-dependent resistance status value, preferably varistor ceramic, be what What is achieved is that local overvoltages are derived that can. Of course, this can also be done in accordance with the say 14 or 15 trained carrier assembly from the be made of the same material.

The sliding element can be preferred according to claim 21 Way be designed as a pin and egg under the pressure ner spring arrangement are available so that when the Verklinkungsstelle changes its position, for. B. from the Shell pops out.

According to claim 23, there is the possibility of switching Mechanism with a lock by a spring element form, which is a cone, which is from the force spring is loaded, holds at nominal current and releases at overcurrent. The spring element can correspond chend claim 24 made of bimetal or a Formge memory alloy manufactured and trained.

A lock can also be used as a lock Fusible wire are used, the entge the sliding element against the force of a spring. Once the overcurrent occurs, the fuse wire will melt and the Release the force of the spring. Of course there is also Possibility that the sliding element in a sleeve on a End is held in which a compression spring and the  Fusible wire is added and that the sleeve on the other End has a contact protrusion that with a the non-linear resistor electrically connected which counter contact can be contacted. If the The fuse wire melts and the sliding element faces outwards jumped out, causing the trigger for the Switch disconnector is operated, only needs one new sleeve with the sliding element, the compression spring and the Fusible wire are used, so that the exchange is very is simple.

Further advantageous embodiments of the invention are can be found in the further subclaims.

Using the drawing, in which some embodiments the invention are shown, the invention should be so such as further advantageous refinements and improvements gene and further advantages invention explained in more detail and to be discribed.

Show it:

Fig. 1 shows a circuit arrangement of a network with inserted, non-linear resistors,

Fig. 2 shows a circuit arrangement for just one line conductor,

Fig. 3 shows an arrangement of a nonlinear reflection object,

Fig. 4 is a FIG. 2 similar Schaltungsanord voltage with a non-linear resistor,

Fig. 5 is a circuit arrangement with not li nearem resistor and a fuse,

Fig. 6 shows a device for actuating a release device off, with integrated nonlinear resistor,

Fig. 7 shows another embodiment similar to that of Fig. 6,

Fig. 8 is an enlarged representation of a rich Teilbe of Fig. 7,

Fig. 9 shows another embodiment of the invention with a non-linear resistor and

Fig. 10 is an enlarged view of a rich Teilbe the device according to Fig. 9.

In a medium voltage network according to FIG. 1 there are three network conductors R, S, T in the departure from a transformer station 10 , in which the high voltage coming from the high voltage network R 1, S 1, T 1 is transformed into medium voltage.

The three conductors R, S, T each have a PTC resistor 11 , 12 and 13 serving as a non-linear resistor, to which a non-linear impedance (not shown) is assigned, as well as a disconnector 14 shown in broken lines with contact points 15 , 16 and 17 in the conductors R, S, T. the circuit breaker 14 further includes a switch actuating means 18, which are connected through to lead lines 19, 20, 21, which are connected to a common line 22 to trigger elements 23, 24 and 25th The release elements 23, 24 and 25 are assigned to the PTC resistors 11, 12 and 13 and detect changes in the properties of the PTC-resisting stands 11, 12 and 13, wherein they due to the changes detected via the lines 19, 20, 21, 22 Give signals from which the actuating mechanism 18 is actuated, so that the contacts 15 , 16 and 17 are opened. The PTC resistors 11 , 12 and 13 change when increasing the current values flowing in the conductors R, S, T their temperature and thereby their electrical resistance, so that the current flowing through the contact points 15 , 16 and 17 of the circuit breaker 14 is limited becomes. A wide variety of means can be used as elements for detecting the change in the properties of the PTC resistors 11 , 12 and 13 .

In the embodiment of Fig. 2 shows a device 31 of the voltage across the PTC resistor on the change ge for detecting in parallel with a PTC-resistor 30, whose output signal is fed to the triggering or actuation mechanism 18 via a line 32.

The triggers 23 , 24 , 25 can also be omitted and the PTC resistors 11 , 12 , 13 accommodate the actuating device. Thus, in the embodiment according to FIG. 3, PTC material 34 is located inside a casing 35 which is closed by a lower cover 36 made of electrically conductive material. Between the upper end of the PTC material 34 and an upper end cover 37 there is a free space 38 and this free space is provided because the PTC material 34 when an overcurrent occurs and a subsequent temperature increase in temperature changes its length. To detect this change in length, a plate 39 made of electrically conductive material is placed on the upper, free end of the PTC material, to which an articulated lever arrangement 40 closes, which mechanically controls the actuating device 18 . The sleeve 35 is made of electrically insulating material and on the cover 36 or the plate 39 , a feed conductor 41 or discharge conductor 42 is ruled out, with which the arrangement according to FIG. 3 can be used in the course, for example, of the mains conductor R. The lever mechanism 40 is preferably made of insulating material. The conductor 42 connected to the plate 39 is led out of the space 18 through an opening 43 ; the lever linkage 40 is connected to the plate 39 via a hole 44 . Instead of a sleeve, handrails can also be used, a handrail with tig being able to penetrate the PTC resistor. The material from which the sheath or the holding rods are or be is insulating material, possibly with a non-linear voltage-dependent resistance value, e.g. B. Vari storkeramik.

In the embodiment of FIG. 3 according to, for example, the element 23 can be detected with the changes in the properties of the PTC material 11, quasi with the PTC Wi resistor integrated, and the lever linkage 40 corresponds in function to the line section 19/22.

. In the embodiment of Figure 4, for example, in the power line R is a PTC-resistor 50 is inserted; in parallel, a voltage measuring device 51 is connected, which supplies a voltage signal to an actuator 53 in the form of a piezo element via a line 52 . This voltage causes a change in length of the piezo element 53 , which can be guided to the actuating mechanism 18 via a linkage 54 , so that the contact point 11 can be opened, for example. Instead of a piezo element 53 whose length change is to be used, a piezo element could also be used, the deflection of which can be used; Corresponding piezo materials are, for example, from the Siemens font "Vibrit" piezo ceramic from Siemens, order no. N-281/5053, 190 163 PA 2818.

Another solution is shown in FIG. 5. A PTC resistor 60 is inserted into a conductor R and a fuse 61 is connected in parallel therewith . This fuse 61 is known per se and has a sleeve 62 , one end of which is terminated with a contact cap 63 and the other end of which is terminated with a contact cap 64 . In the contact cap 64 , a guide piece 65 is crimped, in which a pin 66 is guided. Between the pin 66 and the lower cap 63 there is a fusible wire 67 and by means of a spring (not shown in FIG. 5) the pin 66 is acted upon in the direction of arrow A. Via supply and discharge lines 67 and 68 , the cover caps 63 and 64 are connected to the line conductor R, so that the fuse 61 is connected in parallel with the PTC resistor. If an overcurrent now occurs, the resistance of the PTC material will increase sharply so that the current essentially flows through the fuse. Since the fuse wire 67 is melted through and the pin 66 is moved in the direction of arrow A into the dashed position 66 a. This movement of the pin 66 is supplied to the actuation mechanism 18 so that the switch disconnector 14 can be actuated.

A relatively simple backup can be used as a backup be used, which only withstand the tension, but does not have to carry a nominal current. It only needs one small rated current.

Another embodiment of the invention is shown in FIG. 6. A PTC resistor 71 is located within a sheath 70 made of insulating material. In Fig. 6 at the lower end, the sheath 70 is closed with an electrically conductive cap 72 , which cap has a cup shape with an L-shaped edge in cross section 73 with which it closes the lower end of the sheath 70 . On the cap 72 , an electrical conductor is closed, for example a conductor 41 . The upper end of the PTC material ends at a distance from the upper end of the sheath 70 , which is closed there with a cap 74 which is the same as the cap 72 . On the upper end of the PTC material there is an electrically conductive layer 75 , to which a conductor rod 76 is connected, which passes through an electromagnet system 77 . The upper end of the conductor track 76 is connected to the cap 74 in an electrically conductive manner. Within the free space between the cover 75 and the cap 74 is a Schaltme mechanism 78 with a release lever 79 which cooperates with a latch projection 80 on a pin 81 . If the electromagnet system speaks to a magnet armature 82 , within the switching mechanism 78, the release lever 79 is pivoted clockwise and under the pressure of a spring, not shown, after release of the latch 80, the pin 81 is moved in the direction of arrow A, as in the case of arrangement according to FIG. 5, the actuating mechanism 18 is operated to open the switch. The actuating mechanism is then not necessarily a switch lock.

The embodiment according to Fig. 7 shows a similar shape. The PTC material 88 is located within a casing 85 made of electrically insulating material, which is closed at the top and bottom by a cap 86 and 87 . The PTC material has a central opening 89 , which surrounds a conductor element 90 , which the PTC-Wi resistor 88 at its one end in the drawing slightly exceeds. At the other, lower end, a plate 89 a is screwed to the conductor element 90 , which is also in electrically conductive connection with the PTC material 88 . At the free end (in the drawing above) of the conductor element 90 there is a U-shaped contact element 91 , in which a contact pin 92 engages.

Reference is now made to FIG. 8, which shows this area in an enlarged view.

The contact element 91 has two contact legs 93 and 94 , in which the pin 92 engages. The pin 92 is integrally formed on a rotating part 95 , which is attached to the inside of a sleeve 96 made of insulating material at its end facing the conductor element 90 and is crimped therein; the pin 92 protrudes from the sleeve 96 through an opening 97 . The upper end of the sleeve 96 is fixed on a retracted board 98 of the pot bottom 99 of the cap 87 with a flange 91 a. An inner sleeve 100 made of metallic material extends telescopically into the interior of the sleeve 96 and is open to the bottom part of the sleeve 96 and closed in the area of the bottom part 99 of the cover cap 87 . It ends at a distance from the rotating part 95 so as not to have an electrically conductive connection to the rotating part. The outer sleeve made of insulating material 96 has in the area of the flange 91 a lateral openings (not shown), through which molded on the inner sleeve contact springs (not shown) reach out to the rim 98 of the pot base 99 . The inner sleeve 10 is a sliding element and encloses a compression spring 101 , one end of which is supported on the rotating part 95 and the other end of which is supported on the upper closed end of the inner sleeve 100 . The compression spring 101 is surrounded with insulating material, so that a current flow through the compression spring 101 is prevented. Between the upper end of the inner sleeve or a contact plate 102 arranged there and the rotating part 95 , a fuse wire 103 is hen vorgese. So that there is an electrically conductive connection from the contact element 91 to part 92/95 and the BEFE attached to it one end of the fuse wire 103 ; the other end of which is contacted to the board 98 via the contact plate 102 , the inner sleeve 100 and their contact springs which spring radially outward through the outer sleeve. If the fuse wire 103 melts in the event of an overcurrent, then the inner sleeve 100 is driven outward in the direction of arrow A under the pressure of the spring 101 , similar to the pin 81 in the arrangement according to FIG. 5. If the fuse wire 103 has melted, only that is increase sleeve 96 and through a new Hülsenanord voltage with sleeve 96 and replace inner sleeve 100th Possibly. a handle may be attached to the sleeve 96 to facilitate removal and replacement.

In the embodiment according to FIG. 10, the fuse wire is not present. On a screwed in the PTC material 88 conductor element 110 , a guide spindle 111 made of insulating material is screwed, which projects above the upper end of the PTC resistor 88 . The guide spin del 111 is provided in the region of the upper cap 87 with a guide base 112 , into which the lower end of an outer sleeve 113 is pressed, which has a flange at the inner end 114 located inside the guide 112 . A compression spring 115 is supported on this flanging 114 , the other end of which is supported on the inwardly flanged upper end 116 of an inner sleeve 117 . By means of this flanging 116 , the inner sleeve is firmly connected to a rod 118 . This rod 118 engages through the guide region 112 up to the vicinity of the free end of the conductor piece 110 , on which a Fe derelement 119 is attached, which has a U-shape with two legs 120 and 121 , which are approximately V-shaped at their free ends are bent inwards and thus form a constriction 122 . The mushroom-shaped inner end 123 of the rod 118 engages in this constriction 122 and is held by the spring element 119 against the pressure of the spring 115 . With an increased current flow and thus also at elevated temperature, the spring element 119 deforms, in which the two legs 120 and 121 are spread, and thus the rod 118 clears the way, so that this in the arrow direction A under the pressure of the Fe 115 can move outwards. This movement in the direction of arrow A then actuates the operating mechanism 18 of the switch. The material from which the spring element 119 is made can either be a thermobimetal or a shape memory alloy.

The casing 70 or 85 of the designs according to FIGS. 6 to 10 is made of insulating material. In a particularly preferred manner, this insulating material can be varistor ceramic. The reason for using the varistor ceramic is evident from the above-mentioned German patent application.

In the arrangements according to FIGS. 7 to 10, an electrically conductive connection from the lower cap 86 to the PTC material 88 is provided via a stranded wire 130 ; from the upper end of the PTC material to the top cap 87 , another stranded wire 131 is hen vorgese; a certain part of the current now flows over the conductor element 90 and the fuse wire 103 or the Lei terelement 110 and the sleeve 111 or the spring element 119 and the rod 118 to the cap 87th A parallel connection of PTC material 88 and fuse wire 103 or spring element 119 is thereby achieved.

In the arrangements according to FIGS. 7 and 8 or 9 and 10, the fuse wire and the U-shaped spring element 119 with the conductor 118 only need to carry part of the current. In the embodiment according to FIGS. 9 and 10, only the conductor 118 has to be pressed in again, which can be done manually or by remote control. In the embodiment according to FIGS. 7 and 8, only the securing element with the sleeve 96 , the inner sleeve 100 , the fuse wire 103 and the compression spring 101 will have to be replaced. Since these components only have to carry a small portion of the current, since the main current portion leads through the PTC resistor and the stranded lines 130 and 131 , this fuse element can be designed quite inexpensively. If the arrangement according to FIGS. 7 and 8 has responded, only the securing element needs to be replaced with a new one.

The inner sleeves can be used as a sliding element for actuation the switching device or to unlatch a as Switch lock trained actuator be educated.

Claims (28)

1. In at least one network conductor of an electrical network usable electrical switching device which interrupts the at least one network conductor when a certain overcurrent occurs, characterized in that in series with an electrical isolating or load-break switch a non-linear resistor whose resistance value is not linear with increasing current value, it increases, preferably a non-linear resistor with positive temperature coefficient is connected, which limits the overcurrent that occurs to current values that can be switched by the disconnector or switch disconnector. 2. Switching device according to claim 1, characterized ge indicates that parallel to the non-linear resistor a linear or non-linear voltage dependent impe danz, e.g. B. a capacity is switched. 3. Switching device according to claim 1 or 2, characterized characterized in that means for detecting the change in the Properties of the non-linear resistor Current change in the line conductor are provided, which With a signal when the specific overcurrent occurs generate that an actuator for the Switching device can be fed, and that when it occurs of the signal the actuating device the switching device tion operated. 4. Switching device according to claim 3, characterized records that the means the voltage change on not Detect linear resistance.   5. Switching device according to claim 3, characterized ge indicates that the means of changing the geometri dimensions of the non-linear resistance detec animals. 6. Switching device according to claim 3, characterized ge indicates that the means the temperature change of the detect non-linear resistance. 7. Switching device according to one of claims 1 to 6, characterized in that the means for detection voltage change of the non-linear resistance of by an actuator connected in parallel is preferably formed by a piezo element, the Än change in its geometry the actuator for the switching device is actuated. 8. Switching device according to one of claims 1 to 7, characterized in that the non-linear counter stood a switching mechanism with a latching point is assigned with which when an overcurrent occurs and unlatching the latching point of the separating or Switch disconnector can be actuated. 9. Switching device according to claim 8, characterized ge indicates that the switching mechanism is a sliding element is assigned that when the latch is released place the switching mechanism an actuator actuated for the disconnector or switch disconnector. 10. Switching device according to claim 8 or 9, there characterized by that the non-linear resistance a trigger device is assigned, the Schaltme mechanism operated.   11. Switching device according to claim 10, characterized ge indicates that the triggering device is an electroma is a magnetic trigger with an anchor that closes the kungsstelle of the switching mechanism actuated. 12. Switching device according to one of claims 10 and 11, characterized in that on an electrode a conductor is connected to the non-linear resistor which is part of the electromagnetic release. 13. Switching device according to one of claims 8 to 12, characterized in that the non-linear counter stood together with the switching mechanism and / or the Trigger and / or the conductor by means of a carrier arrangement is made of insulating material. 14. Switching device according to claim 13, characterized ge indicates that the carrier arrangement at least one Has support rod made of insulating material, and the linear resistance together with the switching mechanism and / or the trigger and / or the conductor, one unit forms, are held together. 15. Switching device according to claim 14, characterized ge indicates that the handrail is the non-linear Wi the stand penetrated in the middle. 16. Switching device according to claim 13, characterized ge indicates that the carrier arrangement as a housing or Sheath is formed, which is at least the non-linear Resistance encloses. 17. Switching device according to claim 16, characterized ge indicates that the trigger and / or the Schaltmecha arranged in a free interior of the shell are.   18. Switching device according to claim 17, characterized ge indicates that the casing is tubular, preferably zy is lindric, and has caps at its ends, to which an electrical supply or discharge is connected sen, and that the non-linear resistor is electrical is conductively connected to the cover caps. 19. Switching device according to one of claims 13 to 18, characterized in that the insulating mate rial has a non-linear resistance value that art that when an overvoltage occurs the opp level drops. 20. Switching device according to one of claims 12 to 14, characterized in that the insulating mate rial is made of varistor ceramic. 21. Switching device according to one of claims 9 to 20, characterized in that the sliding element as a Zap fen is formed and under the pressure of a spring arrangement voltage from the carrier arrangement, preferably the envelope, pops out. 22. Switching device according to one of claims 16 to 21, characterized in that the non-linear Resistance only partially fills the shell and that between the non-linear resistance and the neighboring one ten electrically conductive free end of the switching mechanism mus and / or the leader and / or the anchor transmit electromagnetic system are housed. 23. Switching device according to one of the previous types sayings, characterized in that the switching mechanism mus with a lock by a locking spring element ge is the one that forms under the pressure of the spring assembly voltage standing, preferably designed as a pin  Holds sliding element and him when an over occurs releases current. 24. Switching device according to claim 18, characterized ge indicates that the detent spring element has a U-shape shows with narrowing of his thighs that from Tempe temperature in the case of material that changes its shape (thermal bimetal or shape memory alloy), and that the Ver engravings behind a mushroom-like extension on the inside Grips the end of the pin and holds it in place. 25. Switching device according to one of claims 1 to 22, characterized in that as a lock Melting wire is provided against the sliding element holds the pressure of a spring and when a Overcurrent melts, so that the spring the sliding ment outwards. 26. Switching device according to claim 25, characterized ge indicates that the sliding element with compression spring and Fusible wire is arranged within a sleeve that is attached to has a contact protrusion at its inner end which with one with the non-linear resistor electrical Conductively connected counter contact is contactable. 27. Switching device according to claim 25 and 26, there characterized in that the sliding element of an In NEN sleeve is formed, which is closed to the outside and is open on the inside and guided in the sleeve, and that the inner sleeve the fuse wire and the Druckfe that surrounds. 28. Switching device according to one of the previous types sayings, characterized in that the not li linear resistance in a main current path and the melt wire or the U-shaped spring in one parallel to it trending current path.