DE464688C - Installation circuit breaker - Google Patents

Description

In the case of automatic switches, including installation automatic switches, the heating of the coil and the contacts has a particularly harmful effect if the automatic switch is approximately loaded by the tripping current for a longer period of time. Particularly when the arc is extinguished, particular difficulties arise when the contacts are heated. It is already known to bypass the coil with an auxiliary switch, which is designed as a heating band and opens in the event of an overcurrent, so that the full overcurrent then excites the trip coil. However, in this way the difficulties of arc extinction are not eliminated, since the main contacts of the known switch are still continuously traversed by current and heat up.
According to the invention it is therefore proposed that the main switch not only bridge the trip coil but also the main contacts and arrange both contacts in a common blow field. The interruption at the auxiliary contact should precede the interruption at the main contacts, "so that before the interruption of the main contacts, the field in the blower coil is so excited that it works with certainty. If a thermostat is used to interrupt the auxiliary contacts, it can either directly act as an auxiliary switch or influence another switch. Furthermore, a special or the tripping device of the main switch can be used for rapid interruption of the auxiliary contacts. A resistor can be connected in the auxiliary circuit, with the help of which the main and auxiliary circuit can be balanced against each other.

This arrangement ensures that the resistance in the machine is proportionate is small. Since the blower coil is only loaded for a short time after the auxiliary circuit has been opened it can be made of thin wires with high resistance; she can also get considerably more turns in the same space, so that both their Induction and resistance increase, thereby limiting the short-circuit current will. In addition, the blowing effect is increased by the higher number of turns.

In the drawing, FIGS. 1 to 3 show various exemplary embodiments of the invention shown schematically.

According to Fig. 1, α is the release and blower coil for the main switch b. In parallel with this, a resistor c and a contact device d, e are connected. When the switch b is switched on, the contact device d, e is inevitably also closed. The majority of the current flows during normal load or in the event of a low overcurrent via the resistor c and the contact device d, e, while only a small part of the current flows via the switch b and the coil α . If the overcurrent persists for a longer period of time, the first expedient as

thermal contact formed contact device d, e respond. If this contact is interrupted, the current flowing through the trip coil α is so great that initially, especially as a result of the blowing effect, any arc on the auxiliary switch is extinguished and switch b is also immediately interrupted. Since so far only very little current has flowed through the main switch,

ίο the contacts are not heated and switching off takes place without an arc. The arrangement can also be such that the resistor c is arranged as a heating winding on one of the contact carriers d, e .

The interruption points of the switch b and the contact device d, e are spatially arranged in relation to one another in such a way that the arcs that occur are extinguished jointly by the blow-out coil α .

ao In Fig. 2, a further embodiment is shown. Here, α is again the trigger and blower coil of the main switch b. The resistor c is arranged as a heating coil on one arm of the switch b .

When the switch is closed, the current flows through the heating winding c via the contact e through the line f. In this case too, only a small part flows via the main switch b to the coil a. The part of the switch b carrying the heating coil is designed as a thermostat and interrupts the shunt line at e. The entire current then flows through the coil a, which then immediately switches off the switch b .

In Fig. 3 a similar embodiment is shown, only. here the trip coil α is not completely bridged by the short-circuit line /, but only part of it. The adjustment of the two coil parts must be done in such a way that the electromagnetic release of the main switch b only takes place when the auxiliary switch has responded due to the thermal effect.

Claims (3)

45 claims: ι. Installation automatic circuit-breaker with a connected parallel to the trip coil auxiliary switch, characterized in that the (d, e) through the auxiliary switch bridged contacts (b) of the main switch "and the" contacts of the auxiliary "switch (d, e) arranged in a common blowout are. 2. Installation circuit breaker according to claim i, characterized in that part of the blowing coil (a) serves as an electromagnet for triggering the main switch (b) and only the remaining part of the coil is shunted to the auxiliary switch (d, e) . 3. Installation automatic switch according to claim ι and 2, characterized in that the auxiliary switch {d, e) is wholly or partially combined with the main switch (b) . 1 sheet of drawings 6ERLtN. COVERED IN DEC