RU2363066C2 - Switch device - Google Patents

Abstract

FIELD: electric engineering.

SUBSTANCE: switch device (3) guarantees time delayed disconnection of switching station by simple means (4). For this purpose movable contact bracket (14) in closed position should be aligned with current lead (12), which is in conducting joint with fixed contact bracket (10). Current lead (12) has the same direction of current as movable contact bracket (14) so that force impact of energy accumulator drive (F3) influencing on movable contact bracket (14) is reduced by impact of electromagnetic retention force (F4) stipulated by electric current, thus making time delayed transfer into open position.

EFFECT: guarantees time delayed disconnection of switching station by simple means.

13 cl, 9 dwg

Description

The invention relates to a switching apparatus.

A switching device or also a protective switching device serves for the purpose of disconnecting or, respectively, connecting one or more current circuits in operating conditions or, accordingly, in emergency situations. Depending on the area of use and the purpose of use in such devices, along with one or more phase wires, a neutral wire can also be switched. The load located in the current circuit, for example, the consumer in this case, under operating conditions or, accordingly, in emergency conditions, must be switched, however, under load only in the current circuit of the corresponding phase conductor and thereby approximately without load, i.e. at a current that is small in relation to the rated current of the corresponding switching device in the current circuit of the neutral wire.

From DE 1062327 B, a switching device is known for electric power sources or, respectively, switchgears with selectively operating circuit breakers for short-circuit currents, in which, for a selective step setting, the switches are in principle of the same design with respect to the moving parts of the switch and interacting with the moving contact The trip units (mechanics) and the excitation links (electrical equipment) are equipped with contacts in which the current flowing through the contacts has an effect that opens contacts or enhances contact pressure.

The basis of the invention is the task of creating a switching apparatus that provides simple means in comparison with the first switching point delayed in time separation of the second switching point.

This problem is solved according to the invention by the features of paragraph 1 of the claims; preferred embodiments are accordingly the subject of further claims.

Due to the assignment of a current lead in an electrically conductive connection with a fixed contact holder to a movable contact holder loaded with a drive force, when current flows, the direction of current flow can be achieved with the current lead so that the drive energy of the energy storage acting on the movable contact holder due to the passage of electromagnetic current holding forces affect in the sense of the electrodynamic binding effect due to the accompanying general of the magnetic field on the current lead and on the movable contact holder, and due to this, by simple means, a time-delayed separation of the switching point is achieved. A load connected to at least a bipolar switching device, for example a consumer, is therefore switched first in the current circuit of the corresponding phase wire and only with a time delay in the current circuit of the neutral wire. At the same time, it was ensured that by means of an arcing chamber located in the area of the switching point belonging to the phase conductor, if necessary, in connection with high-quality contact materials, as well as other measures that contribute to the disconnection of the load, reliable and quick disconnection of the current circuit occurs. Complicated measures, such as a separate arcing chamber for a switching point in the neutral wire current circuit, contact-resistant contact materials, contact-pressing springs, or also a separate release for a movable contact brush can be saved as a result of contact-free contact separation.

Preferably, the current lead in the case of a movable contact carrier in the first switching position is arranged substantially parallel to it so that the magnetic field propagating through these parallel regions of the components creates a sufficiently high holding force.

Advantageously, the conductor is fixedly mounted relative to the housing, due to which there is a strong fixation with respect to the movable contact holder and thereby a guarantee for long-term performance.

The preferred way the conductor is made stepped, in particular, in the form of a stamped-bent product; made in the form of a stamped-bent product, the part can be manufactured particularly efficiently in terms of material consumption and economically.

Mostly the current lead is made together with the conductive path as a solid conductive loop, due to which an easily manufactured and simple current passage is realized.

The invention, as well as preferred forms of execution according to the characteristics of the further claims, are explained in the following in more detail based on the exemplary embodiments shown in the drawing, without limiting the invention; while showing:

Figure 1 schematically shows a switching device with a switching point for a current circuit of a neutral wire and with the following switching point for a current circuit of a phase wire according to paragraph 1 of the claims; and

Figure 2-9 various forms of the conductive loop provided as a part of the switching apparatus, in various representations.

Figure 1 shows a switching device 1 with a housing 2, which has a switching device 3 with a switching point 4 for the current circuit of the neutral wire N and with the following switching point 5 for the next current circuit of the phase wire P. Current circuits of the neutral wire N and phase wire P lead at the ends, respectively, to the schematically presented contact clips 6 and 7 so that, on the one hand, a current source and, on the other hand, a load, in particular a consumer, can be connected. The group of single or multi-pole switching devices includes both contactors, relays and the like, and protective switching devices, such as a linear protection device.

Switching point 4 of the neutral wire N consists of a fixed contact part 8 and a movable contact part 9. A fixed contact part 8 is placed on a fixed contact holder 10, which is part of the G-shaped conductive track 11.

The conductive path 11, for its part, passes into the conducting conductor 12 intersecting it, due to which an integral conductive loop 11, 12 arises. The conductive conductor 12 is held firmly in place at the selected locations using the holders 13 and is made stepwise.

The movable contact part 9 of the switching point 4 of the neutral wire N is located on the movable contact holder 14, which according to Figure 1 is shown in its closed position. In this case, the conductor 12 passes close to and mainly parallel to the movable contact holder 14, while the conductive path 11 is located at a distance to the conductor 12 and the movable contact holder 14. On the axis 15, the movable contact holder 14 is rotatably mounted and thereby deflectable represented by the dashed line open position. The movable contact holder 14 is connected to the flexible line 16, in particular, to a multi-wire flexible wire, which for its part is in electrically conductive connection with the current circuit of the neutral wire N.

By means of the release device 18 physically imparted to the next switching point 5 and the dashed line shown here is the actuating force F1, the movable contact holder 14 can be loaded indirectly through the actuator unit 17 — the drive force F3, which is presented as an action line —. The Executive unit 17 is made in the form of switching mechanics, in particular, in the form of a lock switching device. The actuation force F1 acts simultaneously on the next movable contact holder 19, which is equipped with the next movable contact part 20 and is mounted on the same axis with the movable contact holder 14. The movable contact holder 14, 19 can also be mounted on separate axes. Together with the next fixed contact part 22 installed on the next fixed contact carrier 21, the next switching point 5 is formed for the current circuit of the phase wire P. The current circuit of the phase wire P extends on the sides of the next fixed contact holder 21 through the ear-like area up to the schematically represented arcing chamber 23. On the sides of the movable contact carrier 16, it has - respectively a flexible line 16 - in the same way a multi-wire flexible wire that allows the transition of IG Petritskaya contact carrier 19 from the closed to the open position while maintaining the electrically conducting connection to a circuit of the phase conductor F.

During the intended use of the switching apparatus 1 — shown schematically by arrows of the current flow — the current I flows in the current circuit of the phase wire P through the next fixed contact holder 21, through the next switching point 5 having both contact parts 20, 22, through the next movable contact holder 19 and, finally, through a multiwire flexible wire to a piece of phase wire P, which is stationary relative to the housing. By connecting between the end of the phase wire P and the beginning of the neutral of a conductor N - not shown here - of a consumer, the current circuit can be supplemented, and it is possible to symbolically represent the reverse current flow I through a flexible line 16, a movable contact holder 14, a switching point 4 with corresponding contact parts 8, 9, a fixed contact holder 10 and, finally, through the conductive loop 11, 12.

If now the control or, accordingly, the disconnection of the release 18 occurs in operating conditions or in an emergency situation, the actuation force F1 acts in the same way on the next movable contact holder 19 and on the actuating unit 17. As a result, the next movable contact holder 19 transfers from its closed position in the open position made in the form of switching mechanics, the actuating unit 17 is unlocked by the actuating force F1 so that the movable contact holder 14 due to not The energy storage device presented here, for example, in the form of a switching spring and the resulting actuating force F3, tends to change its closed position to an open position.

The closing spring may be part of the switching mechanics.

The separation of the next switching point 5 is supported by the electrodynamic effect, which occurs due to the directions of the current flow on the next fixed contact holder 21 and the next movable contact holder 19. The electrodynamic effect is manifested in the form of a repulsive force F2 so that the parts located next to and passed by current in the opposite direction repel each other. Since the current I, as shown in Fig. 1, must pass a U-shaped path in the region of the next switching point 5, by means of the resulting and differently acting magnetic fields, the next movable contact holder 19 is repelled with respect to the next fixed contact holder 21.

In contrast to the passage of current in the current circuit of the phase wire P, the current I through the switching point 4 due to the U-shaped embodiment of the fixed contact carrier 10 according to FIG. 1 is guided approximately rectilinearly and thereafter passes the conductive loop 11, 12. Designed as part of the conductive loop 11, 12, the current lead 12 passes in parallel and with a small distance relative to the movable contact holder 14, which results in the passage of current in the same direction. Since parts passed by current in the same direction are mutually attracted due to an equally acting magnetic field, the crucial electrodynamic effect can be used. This electrodynamic effect is manifested, however, through the holding force F4, which counteracts the driving force F3 in such a way that there is a reduction in the driving force F3.

The decrease in the action of the driving force F3 causes, in comparison with the control time of the next movable contact holder 19, a time-shifted opening of the switching point 4. Due to this targeted direction of current flow, the electrodynamic effect appears on the next switching point 5 of the phase wire P in the form of a repulsive force F2, on the contrary, can also be made useful as a holding or blocking force F4. This measure leads to the fact that the switching point 4 due to the lag of the movable contact holder 14 relative to the next movable contact holder 19 is disconnected only after the next switching point 5 and thus first disconnects the under-load phase wire P and then disconnects the free neutral wire N.

Correspondingly, when an electric arc is activated or tripped when switching device 1 is in load mode, the electric arc loads only the next switching point 5 of the phase wire P, which is equipped with an existing arcing chamber 23 in one way or another, in order to possibly quickly extinguish the electric arc, while observing the given switching sequence. Since in the switching point 4 no electric arc occurs, the execution of the current circuit of the neutral wire N in comparison with the phase wire P can be done by simpler means; this includes a smaller volume of contacts, more favorable contact materials, smaller cross-sections of wires and the exclusion of both its own release and its own arcing chamber.

The so-called current contraction forces that can appear on both switching points 4 or 5 in the region of current contraction between contact parts 8 and 9 or, respectively, between contact parts 20 and 22, affect the electrodynamic effects in the switching point 4 of the neutral wire N or, respectively, in the next switching point 5 of the phase wire P only to a limited extent. Since a partial U-shaped direction of the current and thereby an undesirable current flow in the opposite direction due to the repulsive force should take place through the region of current contraction in the switching point 4, this repulsive force is not only compensated by the holding force F4 created by the current conductor 12, but is provided the resultant and defining time delay force.

The magnitude of the holding force F4 in this case depends on the magnitude of the current I; the higher the current I to be switched, the greater the holding force F4, since the current strength is a measure of the magnetic field strength that attracts the movable contact holder 14 to the conductive wire 12. Similarly, the holding force F4 is determined by the length and distance located approximately parallel to being in a closed position, the movable contact holder 14 of the current lead 12; the longer the current lead 12 runs parallel to the movable contact holder 14 and the smaller the contact-free distance between these parts, the greater the holding force F4. Undesirable side effects that appear during the switching process under certain conditions, such as vibration, heating, or wear of the contact parts 8, 9 of the switching point 4 can be eliminated by a suitable choice of the parameters mentioned above.

In order to close both switching points 4, 5 again, that is, to move both movable contact holders from open to the corresponding closed position, it is possible, for example, to manually return the actuating unit 17 by means of the lever of the switching device or also a return pulse using, if not shown here, remotely controlled return facility. The design of the switching apparatus 1 can be performed in such a way that the movable contact holder 14 of the switching point 4 brings its movable contact part 9 into the closed position with the corresponding stationary contact part 8 before the next movable contact holder 19 sits its next movable contact detail 20 to the next stationary contact part 22. In this case, the contact gap between the fixed and movable contact part 8 and 9 of the switching point 4 can establish tsya also in the case of burned and constructively contacts due tolerances smaller than mezhdukontaktny gap between the fixed and movable contact pieces 20 and 22 following the switching point 5.

Figure 2 and 3 or, respectively, 4 and 5 shows as part of the switching device, a specific conductive loop 11, 12 in a planar and perspective view. In this case, the conductive loop 11, 12 contains, as a single unit, firstly, a current lead 12 bent twice in the form of steps and, secondly, a conductive path 11 bent twice counterclockwise, which is provided with a fixed contact holder 10 at its free end. The conductive loop 12 or, respectively, each of its component parts is installed fixed relative to the housing. The conductive track 11 is approximately G-shaped and can, as shown in FIG. 3, be made in the form of a stamped-bent product from the main material of the conductive path 12. The resulting result is the position and shape of the conductive loop 11, 12 relative to the movable contact holder 14 according to FIG. 1, the current passage provides the desired electrodynamic effect causing the holding force F3.

Figures 6 through 9 show the following embodiments of the conductive loop 11, 12 in various representations. The conductive path 11 according to Fig.6 and 7 is approximately G-shaped, while according to Fig.8 and 9 an L-shape of the conductive path 11 is provided.

The invention explained above can be summarized as follows:

To create a switching device 1, which provides a simple means of time-delayed disconnection of the switching point 4 in the current circuit of the neutral wire, it is provided that the movable contact holder 14 in the closed position is assigned to the current lead 12, which is in an electrically conductive connection with the stationary contact holder 10 and has the same the movable contact holder 14 the direction of current flow so that the force acting on the moving contact holder 14 of the drive Ia F3 power storage due to impact force caused by the passage of electromagnetic holding force F4 current decreases, and thus there is delayed by the time shift to the open position.

Claims (13)

1. Switching device (1)
with a fixed contact holder (10) and with a movable contact holder (14) of a switching point (4) in the neutral wire current circuit;
with the next fixed contact holder (21) and with the next movable contact holder (19) of the next switching point (5) in the current circuit of the phase wire;
with a release (18) for the load of the next movable contact holder (19), on the one hand, and for the load of the actuator unit (17) on the other hand;
moreover, by means of the actuating unit (17), the movable contact holder (14) and by the release (18), respectively, the next movable contact holder (19) are translatable from the first switching position to the second switching position;
moreover, the movable contact holder (14) in the first switching position is associated with the current path (12), which is in an electrically conductive connection with the stationary contact holder (10) and has the same direction of current flow as the movable contact holder (14) so that it acts on the movable contact holder ( 14) in the current circuit of the neutral wire, the drive force (F3) of the energy storage device decreases or is accordingly destroyed due to the passage of current by the electromagnetic holding system oh (F4) and thus, compared with the next movable contact holder (19), the delayed transition of the movable contact holder (14) to the open position occurs in the phase circuit current circuit, due to which there is an almost load-free disconnection of the switching point in the neutral circuit current circuit . 2. The switching apparatus (1) according to claim 1, wherein the actuating unit (17) is made in the form of switching mechanics, in particular in the form of a lock of a switching device. 3. The switching apparatus (1) according to claim 1 or 2, wherein the energy storage device is part of the actuating unit (17), in particular, switching mechanics. 4. The switching apparatus (1) according to claim 1, wherein the movable contact holder (14) is rotary. 5. The switching apparatus (1) according to claim 1, wherein the conductive wire (12) with the movable contact holder (14) in the first switching position is located mainly parallel to it. 6. The switching apparatus (1) according to claim 1 or 5, wherein the current lead (12) is fixedly mounted relative to the housing. 7. The switching apparatus (1) according to claim 1 or 5, wherein the conductor (12) is made stepped, in particular in the form of a stamped-bent product. 8. The switching apparatus (1) according to claim 1 or 5, wherein the current lead (12) together with the conductive path (11) is made as a single conductive loop (11, 12). 9. The switching apparatus (1) according to claim 8, wherein the partial region. the conductive track (11) is located at a distance relative to the conductors (12), on the one hand, and relative to the movable contact holder (14) located in the first switching position, on the other hand. 10. The switching apparatus (1) according to claim 8, wherein the conductive wire (12) is made G-shaped, angled, or approximately S-shaped. 11. The switching apparatus (1) according to claim 8, wherein the conductive path (11) is made in the form of a stamped-bent product obtained from the current lead (12). 12. The switching apparatus (1) according to claim 1, wherein the fixed contact holder (10) is part of the conductive path (11). 13. The switching apparatus (1) according to claim 1, wherein the release (18) has a thermal and / or electromagnetic function.

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