EP0072566A2 - Electric switching apparatus with bridging contacts - Google Patents

Abstract

A switching apparatus is described, especially a contactor, which has at least one double-contact point (6, 7) to which at least one semiconductor valve (4) is connected in parallel. Because of the arc which occurs on opening of the double-contact point, the semiconductor valve (4) is driven such that the arc current is commutated on the semiconductor valve and is extinguished by the semiconductor valve as it passes through zero. The arc is used to trigger the semiconductor valve; in this case the control connection is connected via a braided cable to the contact link. <IMAGE>

Description

The invention relates to an electrical switching device according to the preamble of claim 1. It relates in particular to a contactor, each with a contact bridge bridging each double contact point.

AC switching devices with a high switching frequency, particularly at higher rated currents and in heavy load operation, show considerable wear and tear on the contact and extinguishing system due to the switching arcs that occur, which reduces their service life and causes maintenance costs. Hybrid switching systems have therefore been proposed for such fields of application, in which the load current commutates after opening the main contacts on a secondary path and is switched off there by built-in semiconductor valves at zero crossing. An additional disconnection point in the circuit can, if necessary, be formed by a further contact which is in series with the hybrid switch system and always opens when de-energized.

When using controllable semiconductor valves in the bypass of the mechanical switching point, there is a need to ignite these valves immediately after the opening of the contact piece in order to take over the load current and to minimize the effects of the switching arcs that form. In previously known arrangements for this are _H used ilfskontaktsysteme or external electronic control circuits; both solutions require additional effort and thus increased costs. Very high demands are to be placed on the reliability of these auxiliary arrangements, since the hybrid switch cannot successfully switch off the load current if the ignition of the valves fails due to the absence of further arc extinguishing devices.

It is therefore an object of the present invention to demonstrate ignition methods for controllable semiconductor valves used in the manner described, which are characterized by the least possible outlay on equipment and high reliability, can be easily integrated into new designs of hybrid switches and, if appropriate, can be retrofitted to existing conventional switching devices.

This object is achieved in that at least one controllable semiconductor valve is connected in parallel to each contact point, and in that the control connection is connected via an ohmic or inductive resistor between the contact points of each double contact point, so that the arc which arises when the contact points are separated, at least one contact point causes the semiconductor valve to ignite and the arc current commutates onto the semiconductor valve that has become conductive.

In the event of a switching operation, as is known, the switching arc occurs between the contact pieces of the contact point. This creates a voltage drop at the base points, which can be used to ignite the semiconductor valve. A particularly advantageous embodiment of the invention or application can be seen in the fact that, in particular in the case of a contactor which has double contact points, are bridged / with contact bridges, the control connection is connected to the contact bridge via a stranded wire.

An electrical switch, in which the current is commutated through the contacts to a semiconductor valve, has become known from _DE-O S 1909085. There, however, there are no two contact points, but only one, which is also designed as a rolling contact surface, such that the internal resistance of the contact point is changed when the contact surfaces are rolled onto one another. Accordingly, the control connection of the semiconductor valves is also arranged at any point on the two rolling surfaces. In any case, this arrangement cannot be used for contactors.

From DE-OS 2 612 437 an electromagnetic switching device has become known in which a controllable semiconductor valve is connected in parallel to a single contact point. To control this semiconductor valve, however, an auxiliary contact point is required, which requires an additional complex construction.

The invention is to be explained and described in more detail with reference to the drawing, in which some exemplary embodiments of the invention are shown.

• Fig. 1 bis Fig. 7 unterschiedliche Ausgestaltungen des erfindungsgemäßen Schaltgerätes.

It shows:

• Fig. 1 to Fig. 7 different configurations of the switching device according to the invention.

A first embodiment of the invention is shown in Figures 1 to 3. The switching device, which is not shown, but which can be designed as a contactor, has a contact bridge 1 which can be actuated in a known manner and bridges two contact points 6 and 7 of a main current path provided with connecting terminals 5 and 8 in the switching device. FIG. 1 shows the switch with open contact points 6 and 7, FIG. 2 shows the switch with closed contact points 6 and 7, with a current I shown in broken lines flowing from the connecting terminal 5 to the connecting terminal 8, and FIG. 3 shows the contact points 6 and 7 in the open state, an arc 10 and 11 being drawn between the contact pieces 6a and 7a on the contact bridge 1 (movable contact pieces 6a and 7a) and the fixed contact pieces 6b and 7b. In parallel to the contact points 6 and 7, a controllable semiconductor valve 4 is provided, the control connection 3 of which, with the interposition of a resistor 2 on the contact bridge 1 between the two contact points 6 and 7

connected. In the embodiment of Figures 1 to 3, a double break system is used as a hybrid switching system and, as mentioned above, the load current flows from the terminal 5 via the contact point 6, the contact bridge 1 7 and the contact point 7 to the connection point 8. The voltage drop at the closed contact point 7 is so low that no effective control current is formed from the control connection 3 to the reference connection 9 of the triac 4. The Triac 4 thus remains without power. If the movable contact bridge with the contact pieces 6a and 7a is mechanically separated from the fixed contact pieces 6b and 7b in a manner known per se, the arcs 10 and 11 are drawn, as mentioned above, which only have a low operating voltage at the start of the switching operation ( in the order of 20 volts). The contact bridge 1 thus has a potential difference with respect to the terminal 8, which generates a control current via the resistor 2 and drives the control connection 3 of the triac 4 to the reference connection 9. This triggers the triac and takes over the load current from the mechanical contact system. As a result, the arcs 10 and 11 extinguish, so that the contact bridge 1 is no longer connected to the main circuit. A recent firing of _T riacs by a control current can not be done with it and the after-load current is interrupted at the zero crossing, to avoid a backfire.

FIG. 4 shows a further arrangement in which, instead of a triac, two reverse-blocking thyristors 12 and 13 connected in anti-parallel are provided. The mode of action is then the same; the control connections of the thyristors 12 and 13 are connected together via additional diodes 14 and 15, which ensure the function in a manner known per se, and are connected to the contact bridge via the shared resistor 2.

In the figure 5, the electrical effect of the arc is utilized in that in the secondary or parallel circuit in two ntiserie _A-connected, reverse conducting thyristors are arranged. 16 and 17 The control connections 18 and 19 of these two thyristors are connected directly to one another and via the common resistor 2 to the contact bridge.

The arrangements according to FIGS. 1 to 3, 4 and 5 have in common that in addition to the described effect when switching off, the formation of 'arcing' is avoided when switching on, since when a potential difference between the contact bridge and the respective reference connection of the contact bouncing occurs each acting controllable semiconductor valve, the ignition process is eiöst in the manner described above from ^g and thus the bounce layer sheets are deleted. Depending on the position of the switch-on points of the contact points 6 and 7 relative to one another, the entire switch-on current can also be taken over by the controllable semiconductor valve or valves Design resistor 2 so that it limits the control current for the valves to the maximum permissible value when the full load circuit voltage is applied. This circuit arrangement, with which the method according to the invention can be carried out, can be used in any conventional switching device with a double interruption system (for example in every contactor, motor protection switch and the like), since only a flexible connection with a small cross section is provided between the contact bridge 1 and the resistor 2 with which the control current for the control connections is taken.

The method described can also be used when switching arcs of electromagnetic relays of low power are extinguished. Such a circuit arrangement is shown in the figure. 6. In the main line between the terminals 5 and 8, two make contacts 20a and 20b are connected, which are connected in series via a connecting line 20. The electrical meaning of this connecting line 20 corresponds to that of the contact bridge 1 in FIGS. 1 to 5. The normally open contact pieces 20a and 20b are actuated by an electromagnetic relay 20c. The ignition of the triac 4, which is connected in parallel to the two normally open contacts 20 a and 20 b (one can also say that it lies between the connections 5 and 8) takes place in the manner in which it is arranged for the arrangement. 3 is described. The arc between one of the two contact points 20a or 20b generates a voltage drop, as a result of which a potential difference between the control connection and the reference connection of the Tnac 4, not shown in FIG. 6, causes the Tnae 4 to be ignited.

In Figure 7, the arrangement according to. FIG. 6 modified to the extent that a make contact 21 is additionally actuated by the Ralais 20c, which contact is designed such that it lags behind the contact openings of the two contact points 20a and 20b. For a single-phase, mains frequency application, the contact 21 For currentless switching, open at the earliest 10 milliseconds using the hybrid system consisting of contact points 20a, 20b and triac 4. This arrangement significantly increases the switching capacity of the relay for alternating current.

The advantage that is achieved with the switching device according to the invention, which is realized in FIGS. 1 to 7, consists mainly in the fact that the switching contacts in the hybrid switch are protected, the circuit arrangements for the switching devices as such being very simple. The arrangement can best be used in AC switching devices, it being possible, where appropriate, to use two semiconductor valves connected in anti-parallel or, as described above, a triac.

Claims (2)

1. Electrical switching device with at least one double contact point (6,7; 20a, 20b), each with two fixed contact pieces (6b, 7b) and two movable contact pieces (6a, 7a) cooperating with the fixed contact pieces, characterized in that parallel to each double contact point (6,7; 20a, 20b) at least one controllable semiconductor valve (4; 12,13; 26,17) is connected, and that the control connection (3; 12,13; 18,19) via an ohmic or inductive resistance between the Contact points of each double contact point is connected, - so that the arc which arises when the contact points are separated causes at least one contact point to ignite the semiconductor valve and the arc current commutates onto the semiconductor valve which has become conductive. 2. Electrical switching device according to claim 1, in particular contactor, each with a double contact point (6, 7) bridging contact bridge, characterized in that the control connection (3) on the contact bridge (1) is connected via a stranded wire.

Images