EP2992543A1 - Switch unit, in particular a circuit breaker - Google Patents

Abstract

The invention relates to a switch unit, in particular a circuit breaker, comprising a contact slide unit which comprises a contact slide (1) as well as a fixed contact piece and a moveable contact piece (2,3), and a short-circuit release (4) which acts upon the moveable contact piece (3) by means of a tappet in the event of a short-circuit. Said invention is characterized in that the switch unit comprises a moveable brake device which is designed such that in the event of a short-circuit, the moveable brake device dampens the movement of the rebounded, moveable contract piece (3).

Description

 international version

 description

The invention relates to a switching unit, in particular a circuit breaker, with a contact slide unit having ei ^¬ NEN contact slide and a fixed and a movable contact piece, and a short-circuit release, which acts on a push rod in the event of a short circuit on the movable contact piece.

Switching units, in particular circuit breakers, serve, among other things, the safe switching off in the event of a short circuit and thus protect consumers and systems. Further, electrical or mechanical switching units are suitable for ^¬ be instinctive, manual switching of consumers and for the safe separation of a plant from the power supply during maintenance work or changes in the plant. Electrical switching units are often operated electromagnetically.

That is, such switching units are high-quality electrical switching devices with integrated protection for Mo ^¬ gates, lines, transformers and generators. They are used at workstations with lower switching frequency. Such switching units are suitable in addition to the short circuit protection for overload protection.

In the case of a short circuit, an electrical switching ^¬ unit safely disconnects an electrical system. Thus, this provides a protection against overload. Every conductor through which electricity flows heats up more or less. The heating depends on the ratio of the current to the conductor cross section, the so-called current density. The current density must not be too large, otherwise the conductor insulations may be spattered or possibly cause a fire due to excessive heating. To protect electrical equipment against these damaging effects, switching units are used as overcurrent protective devices. Circuit breakers have two separate release mechanisms for overload and short-circuit protection. Both triggers are connected in series. The short-circuit protection is provided by an electromagnetic release that works almost instantaneously. In the event of a short circuit, the electromagnetic release unlocks without delay a circuit breaker of the circuit breaker. A switching armature disconnects the contactor before the short-circuit current can reach its maximum value.

Known switching units have a contact slide unit with a contact slide and a movable contact piece. The movable contact member further includes electrical contacts ^¬ Kon. Furthermore, such switching units have first contacts to a power line. In an on state, the electrical contacts of the movable contact piece contact the fixed contacts of the switching unit. In the short ^{¬ case} , the electrical contacts of the movable contact piece are released from the fixed contacts, so that the flow of current is interrupted. Here, the movable contact is released from the fixed contacts. By short-circuit shutdowns in a switching unit, however, it may come to the rotation of the movable contact piece about its longitudinal axis after releasing the movable contact piece. When the movable contact piece rotates about its longitudinal axis, this is also referred to as a bridge rotator. That is, the movable contact piece then returns after the rotation is no longer in its original position, but remains in the rotated position.

Known contact slides of switching units often have two guide systems, an inner and an outer guide ^¬ system. The outer guide system is used when the switching operation, that is, the switching on or off, via a switching mechanism of the switching unit. This does not create a bridge twister. The inner guidance system is used in the case of short-firing if the switching operation is achieved via a switching armature, frequently a tappet, the switching unit. follows. That is, when switching off due to a Kurzschlus ^¬ ses the movable contact piece along the inner guide system ahead of the contact slide, bounces on Aufschlag ^¬ surfaces in the so-called lower part of the switching unit and flies back along the inner guide system.

In this case, it flies against the switching armature or the plunger of the switching unit. It may happen that the movable switch piece and plunger meet outside ih ^¬ rer center lines, so that this can lead to a rotation of the movable contact member about its longitudinal axis.

When the movable contact piece remains in the rotated state, meeting at a next switching on the switching unit no longer meet the contacts, in particular silver contacts of the movable contact piece and the fixed contacts of the switching ^¬ unit each other, so that it comes to failure. In other words, a switching piece that remains in a twisted position is disadvantageous because the switching unit is then no longer operational. A not working

Switching piece and a non-functioning switching unit are detrimental to the electrical loads and the system in which the switching unit is installed.

Another problem is that in the event of a short circuit, the circuit breaker does not interrupt the short circuit current fast enough. In this case, three contact-opening mechanisms act staggered over time. The short-term vorüberge ^¬ immediate contact opening due to a current flow takes place on the one hand via current forces at the contact point between the fixed and movable contact members and others about an electromagnetically driven by the short-circuit release pin. The permanent contact opening is made via a mechanical linkage chain to be unlatched in conjunction with a shift lever.

The problem now is when such a high short-circuit currents occur ^¬ that the timing of the opening contact Me ^¬ mechanisms no longer work. The then very present large current loop forces lead to such a high Be ^¬ acceleration of the moving contact that is as fast reflected back from the stop of the housing, that the contact is closed again before the switch mechanism can be kept permanently open via the shift lever. The consequence of this can be the destruction of the device.

Accordingly, the object of the present invention, since ^¬ rin, to provide a switching unit, which the timing of the contact-opening mechanisms reliably ensured even at high short-circuit currents.

This object is achieved by a switching unit, in particular a circuit breaker, with the features of claim 1. Further embodiments of the

Invention will become apparent from the dependent claims, the description and the drawings.

According to the invention this object is achieved by a switching unit, in particular a circuit breaker, with a contact slide unit having a contact slide and a fes ^¬ tes and a movable contact piece, and a short ^¬ circuit trigger, which acts on a short stroke on the movable contact piece via a plunger.

The invention is characterized in that the

Switching unit comprises a movable brake device which is designed such that in case of short circuit, the movable brake device dampens the movement of the rebounded, movable contact piece.

The invention makes use of the physical principle of energy exchange in the collision of two bodies. If two bodies bang together, their velocities change analogously to their mass ratios. The contact piece rebounding from the housing meets a mass. The speed of the switching piece is significantly slower ^¬ velvet and thus the time to reach the fixed contact make extended. This time delay is sufficient for the switch lock to be able to travel the way to a permanent minimum contact opening width. In a particularly advantageous embodiment, it may be provided that the movable contact piece is guided on a guide element, wherein the movable Bremsvorrich ^{¬ tion is} disposed above the movable contact piece and at the upper end of the guide element. According to the invention, the guide element is preferably designed as a guide pin and has a region of greater mass. The center of mass is above the moving contact. The mass is moved to the current dynamic lifting of the contact piece by the plunger of the short-circuit release in the return trajectory of the contact piece. The resulting inevitable collision with the on the return flight ^¬ sensitive switching piece leads to the desired time delay. The advantage of this embodiment is that the assembly is easy to accomplish and also a leadership function of the bridge against rotation is realized.

In addition, it can furthermore be provided that the movable braking device in the form of a mass is a flat-shaped metal part produced by means of stamping technology. With this particular embodiment, the advantage is associated that stamped parts are kostengüns ^¬ tiger. In addition, the flat shape of the metal part reduces the insulation distance between the two switching poles, so the L and the T-side, far less than a mass equal, asymmetric rotary part. It also requires a smaller space.

In a further development of the above embodiment, it may be provided that in addition at the bottom of the leadership element further movable brake device is integrally ^¬ arranged. In this embodiment, a second mass is positioned in addition to the first mass below the movable contact piece. Both masses are together connected to a double mass, preferably by an opening breakthrough located in the switching bridge. They are also arranged axially displaceable in the direction of the contact opening. At stromdynamischer contact bridge opening suggests the

Switching bridge against the contact load spring in its opening movement, first against the mass arranged below, be ^¬ accelerates and is thereby slowed down.

The bridge and double mass fly up to the possibly different housing stops and rebound from there. Advantageously, the housing stop of the double ^¬ mass is further away from the contact point as the contact ^¬ bridge. This means that the bridge is already on its way back and again collides with the still flying double mass, whereby it gives off further kinetic energy, so that the bridge is further slowed down. The ^preloaded contact ^{load spring} moves both parts back towards contact. The advantage of this embodiment is on the one hand in the enormous speed damping and on the other hand in the guiding function of the bridge, which protects against rotation.

In a further advantageous embodiment, it is provided that the movable brake device is arranged on the plunger of the short-circuit release. This embodiment is characterized by a very simple installation.

The switching unit according to the invention has a Kontaktschie ^¬ bereinheit with a contact slide and a fixed and a movable contact piece, which are arranged opposite to each other. Above the contact slide unit, a plunger of a short-circuit release is arranged. In ei ^¬ nem advantageous embodiment can be provided that on the plunger at the end, which is the contact slide fed ^¬ Wandt, a tubular extension is formed which is integrally connected to either of the plunger or is molded as a separate part on the plunger. This tubular extension ent ^¬ speaks in this embodiment of the mass that forms the braking device. The movable contact piece has an opening in which the guide element is positioned. The guide ^¬ element preferably has above the movable switching piece designed as a mass braking device. Before ^¬ preferably a further additional mass may be arranged as Bremsvor ^¬ direction and below the movable contact piece on the guide element. When triggered, the plunger of the short-circuit release moves in the direction of the movable switching piece.

The invention is characterized in that by positioning ^¬ at least one additional mass which serves as a braking device, an energy exchange is caused by the impact of two bodies, which leads to Geschwindigkeitsreduzie ^¬ tion of the movable contact piece. The additional masses for the braking device according to the invention are at least in two embodiments on the guide ^{element is} arranged, which leads the movable contact piece. As a result of this embodiment according to the invention, the guide element has a double function. On the one hand it serves as a braking device to the speed of the movable, rebounded

Reduce contact piece in case of tripping. On the other hand, the guide element guides the movable contact piece, so that rotations of the contact piece due to a high Bewegungsimpul ^¬ ses be reliably avoided. The inventive

Switching unit thus allows reliable even at high short-circuit currents, the timing of the contact-opening mechanisms.

Further advantages and embodiments of the invention will be explained below with reference to embodiments and with reference to the drawing. Here are shown schematically:

Fig. 1 in a schematic sectional view of a first embodiment of a switching unit according to the invention with a contact slide and a short-circuit release with a braking device according to the invention in the form of an additional mass in the on state; FIG. 2 is a schematic sectional view of the embodiment according to FIG. 1 in the case of a short circuit; FIG.

3 shows a schematic sectional view of the embodiment of Figures 1 and 2 during the bridge reflection of the movable contact piece on the braking device ..;

4 shows a schematic sectional view of the embodiment according to FIGS. 1 to 3 with a contact point held open by the switching ^mechanism ; 5 shows a schematic sectional view of a second exemplary embodiment of a switching unit according to the invention with a contact slide and a short-circuit release with a braking device according to the invention in the form of a double mass in the switched-on state;

FIG. 6 is a schematic sectional view of the embodiment according to FIG. 5 in the case of a short circuit; FIG.

7 shows a schematic sectional view of the exemplary embodiment according to FIG. 6 in the case of a short circuit, wherein the

 Housing stop of the movable contact piece is shown;

8 shows a schematic sectional view of the embodiment according to FIGS. 5 to 7 during bridge reflection of the movable contact piece on the braking device;

9 is a schematic sectional view of the embodiment according to FIGS. 5 to 8 with a through the

Switch lock held open contact point;

10 is a schematic sectional view of a third embodiment of a switching unit according to the invention with a contact slide and a short-circuit release with a brake device according to the invention in the form of a tubular body-like extension of the plunger of the short-circuit release in the on state;

Figure 11 is a schematic sectional view of the Ausfüh tion of Figure 1 in the event of a short circuit.

12 is a sectional view of the embodiment of Figures 10 and 11 during the bridge reflection of the movable contact piece on the braking device ..;

Fig. 13 is a sectional view of the embodiment of Figures 10 to 12 with a ge through the switching lock held contact.

FIG. 14 is a prior art path-time diagram for the movable contact; FIG.

Fig. 15 shows an inventive path-time diagram for the embodiments with an additional mass as Bremsvor ^¬ direction or with a tubular body Fortsat on the plunger as a braking device for the movable switching ^¬ piece; 16 shows an inventive path-time diagram for the ^exemplary embodiment with a double ^mass according to the invention as a braking device for the movable contact piece.

17 is a perspective view of a further embodiment of a switching unit according to the invention with a short-circuit release with a braking device according to the invention in the form of a mass, which is produced as a flat metal part by means of punching technology. 1 shows a first ^exemplary embodiment of a switching unit according to the invention with a contact slide unit, which has a contact slide 1 and a fixed and a movable contact piece 2, 3, and a short-circuit release 4, which acts via a plunger 5 in the event of a short circuit on the movable contact piece 3. The movable contact piece 3 has an opening 6, through which a guide element 7 is guided. The guide element 7 is above the movable

Switching piece 3 is formed with a mass 8, which is arranged on the movable contact 3, that they in the event of short circuit, the movable contact 3 from the fixed

Switching piece 2 separates when the plunger 5 hits the mass 8.

The center of mass of the mass 8 is above the bewegli ^¬ chen contact piece 3. Below the movable contact piece 3, the guide element 7 may be performed either in the housing 9 or Kon ^¬ clock shifter 1 or in a combination of housing 9 and contact slide. 1 FIG. 1 also shows a mechanical kinematics chain to be unlatched in the form of a switching ^lock 10. The switch lock 10 must keep the radio ^¬ tion, the contact link permanently open when triggered.

In FIG. 2, the contact slide unit of Fig. 1 in the off ^¬ solvent case is shown. When triggered, the plunger 5 meets the mass 8 of the guide element 7, whereby the Füh ^¬ approximately element 7 moves back into the guide of the housing 9 and thereby separates the movable contact piece 3 from the fixed contact piece 2.

Fig. 3 shows the first embodiment according to FIGS. 1 and 2 during the bridge reflection of the movable contact piece 3 on the braking device, which is formed in the form of the mass 8 on the guide element 7.

4 shows the embodiment according to FIGS. 1 to 3, wherein the contact bridge is held in the opened state by the switching mechanism 10.

Fig. 5 shows a second embodiment of a switching unit according OF INVENTION ^¬ dung with a contact slide 1 and a short-circuit release 4 with an inventive

Braking device in the form of a double mass 11 in the on state. According to the first embodiment, the contact slide unit has a contact slide 1 as well as a fixed and a movable contact piece 2, 3 and a short-circuit release 4, which acts on the movable contact 3 via a plunger 5 in the event of a short circuit. As in the first embodiment, the movable

Switching piece 3 on an opening 6 through which a guide element 12 is guided. The guide member 12 is formed above and below ^¬ of the movable contact piece 3 respectively at the end portions with a mass that characterizes the dung OF INVENTION ^¬ braking device according to the second embodiment in the form of a double mass. 11 The mass is such ausgebil ^¬ det above the movable contact piece 3, that separates the movable contact 3 from the fixed contact piece 2 in the case of short circuit, when the plunger 5 hits the ground. The mass below the movable switching ^¬ piece 3 is designed such that it limits the movement of the movable contact 3 in the event of triggering. ^Accordingly , the guide for the guide element 12 with the double mass 11 in the housing 9 is adapted to the mass below the movable ^contact piece 3. FIG. 5 also shows a mechanical kinematics chain to be unlatched in the form of a switching lock 10. The switch lock 10 must keep the radio ^¬ tion, the contact link permanently open when triggered.

FIG. 6 shows the contact slide unit according to FIG. 5 in the case of release. When triggered, the plunger 5 meets the double mass 11 of the guide member 12, whereby the guide member 12 moves back ^¬ be in the leadership of the housing 9 and thereby the movable contact piece 3 from fixed

Switch piece 2 separates.

Fig. 7 shows the embodiment according to FIGS. 5 and 6 in the case of short circuit, wherein the movements of the movable contact piece 3 on the one hand by the housing stop and the Others is limited by the double mass 11 below the movable contact piece 3.

8 shows the second embodiment according to FIGS. 5 to 7 during the bridge reflection of the movable contact piece 3 on the braking device according to the invention, which is designed in the form of a double mass 11 on the guide element 12. In Fig. 9, the embodiment of FIGS. 5 to 8 is shown, being held by the switching mechanism 10, the Kontaktbrü ^¬ bridge in the open state.

FIG. 10 shows a third exemplary embodiment of a switching unit according to the invention with a contact slide 1 and a short-circuit release 4 with a switching device according to the invention

Braking device in the form of a tubular body-like extension of the plunger 5 of the short-circuit release in the on state. According to the first and second Ausführungsbei- game, the contact slide unit comprises a contact slide 1 and a fixed and a movable contact piece 2, 3 and a short-circuit release 4, which acts via a plunger 5 in the event of a short circuit on the movable contact piece 3. In this third embodiment, the braking device in the form of a tubular body-like extension 13, which surrounds the end of the plunger 5, is formed. FIG. 10 also shows a mechanical kinematics chain to be unlatched in the form of a switching mechanism 10. The switching mechanism 10 has the function of keeping the contact bridge permanently open when triggered.

In Fig. 11, the contact slide unit of FIG. 10 is shown in the case of activation. When triggered, the plunger 5, including the tubular body-like extension 13, strikes the moving contact piece 3, whereby the movable contact piece 3 is separated from the fixed contact piece 2. Fig. 12, the third embodiment according to FIGS. 10 and

11 during the bridge reflection of the movable contact piece 3 on the braking device according to the invention, which is formed in the form of a tubular body-like extension 13 on the plunger 5.

In Fig. 13, the embodiment of FIGS. 10 to

12, wherein the contact ^¬ bridge is held in the open state by the switching mechanism 10.

Fig. 14 shows a path-time diagram for a moving one

Contact piece without inventive braking device from the prior art. It can be seen from the diagram that as much time is needed for the movement in the direction of the housing stop as for the return movement to the fixed one

 Switching piece out, that is, the movable contact piece undergoes this movement without deceleration.

FIG. 15 shows a path-time diagram for an exemplary embodiment according to the invention with an additional mass as

Braking device or shown with a tubular body-like extension on the plunger as a braking device for the movable contact piece. It can be seen from the diagram that the path from the contact contact So to the housing stop S2 equals the course from FIG. 14. However, the path from the housing stop L2 in the direction of contact contact is different. Here, at the point Si, there is the collision and thus the energy exchange between the respective braking device and the movable contact piece. The associated time gain is evident from the diagram in the form of the time interval t ₂ . Due to the time delay, which is caused by the braking device, the operation of the switching mechanism is guaranteed. In Fig. 16, the path-time diagram for the embodiment according to the invention with double mass is shown as a braking device for the movable contact piece. In contrast to the diagram from FIG. 15, an even greater time delay results. tion, which is denoted by t3 in the diagram, by the two-time collision between the upper mass and the movable contact piece and between the lower mass and the movable contact piece. By this time delay the operation of the switching mechanism is secured ^¬ does here.

In Fig. 17, a further switching unit according to the invention with a fixed and a movable contact piece 2, 3 and a short-circuit release 4 is shown, which acts via a plunger 5 in the event of a short circuit on the movable contact piece 3. The guide element 7 is formed above the movable contact piece 3 with a mass 8, which is arranged on the movable contact piece 3 such that in the event of a short circuit, the movable contact piece 3 from the fixed

Switching piece 2 separates when the plunger 5 hits the mass 8. The mass 8 is formed in this embodiment as a flat-shaped metal part, which was produced by means of stamping technology.

The invention is characterized in that by positioning ^¬ tion of at least one additional mass, which serves as a braking device, an energy exchange is caused by the impact of two bodies, which leads to speed reduction of the movable contact piece. The additional masses for the braking device according to the invention are arranged at least in two embodiments on the guide element, which guides the movable contact piece. Through this OF INVENTION ^¬ dung-type configuration of the guide element is a double function to. On the one hand, it serves as a braking device to reduce the speed of the movable rebound Schaltstü ^¬ ckes in the event of triggering. On the other hand, the guide element guides the movable contact piece so that rotations of the contact piece due to a high momentum of movement are reliably avoided. The switching input ^¬ standardized according to the invention thus makes it possible also reliable at high short-circuit currents ^¬ the timing of the contact-opening mechanisms.

Claims

claims

1. switching unit, in particular circuit breaker, with a contact slide unit having a contact slide (1) and a fixed and a movable contact piece (2, 3), and a short-circuit release (4) via a plunger (5) in the event of a short circuit to the movable Switching piece (3) acts, characterized in that

the switching unit has a movable brake device which is designed in such a way that, in the event of a short circuit, the movable brake device dampens the movement of the rebounded movable contact piece (3).

2. Switching unit according to claim 1, characterized in that the movable contact piece (3) is guided on a guide element (7), wherein the movable braking device in the form of a mass (8) above the movable contact piece (3) and at the upper end of the guide element (7) is arranged.

3. Switching unit according to claim 2, characterized in that the movable braking device in the form of a mass (8) is a manufactured by punching technique, flat-shaped metal part.

4. Switching unit according to claim 1, characterized in that the movable contact piece is guided on a guide element (12), wherein the movable braking device in the form of a double mass (11) above and below the movable ^¬ union switching piece (3) and at the two end of the guide element (12) is arranged.

5. Switching unit according to claim 1, characterized in that the movable brake device on the plunger (5) of the short ^¬ circuit release (4) is arranged.

6. Switching unit according to claim 5, characterized in that the movable braking device in the form of a rohrkörper- like extension (13) surrounding the plunger (5) is ^{ausgebil ¬} det.