DE2062174A1 - Electromagnetic contactor with self-holding circuit and undervoltage bridge - Google Patents

Description

ttElectromagnetic contactor with self-holding circuit and undervoltage bridge ' The invention relates to an electromagnetic contactor with a self-holding circuit and undervoltage bridge, which has a relay and a capacitor connected in parallel to the relay, whereby a normally open contact of the relay bridges the self-holding contact of the contactor.

Undervoltage bridges have the purpose of being controlled with contactors Power consumers react after brief voltage interruptions or voltage collapses switch on again automatically. In principle, they are structured in such a way that the Discharge of a capacitor keeps a relay energized for a certain time and keeps the contactor ready to switch on with its contact.

It is an electromagnetic contactor with a self-locking circuit and an undervoltage bridge became known in which the blanking device and the self-holding contact are bridged are through a relay whose Normally closed contact in the control circuit of a Another relay is located, one of which is a normally open contact 4 * n capacitor in parallel with the contactor switches and its second normally open contact bridges the self-holding contact.

This known arrangement allows the contactor to be switched on after brief voltage interruptions or voltage breakdowns, however the disadvantage that the undervoltage bridge is required with two relays for each contactor is what represents a comparatively large effort.

On the basis of this prior art, the object of the invention is to be found based on an electromagnetic contactor with self-holding circuit and undervoltage bridge to create a delayed automatic switch-on in the event of voltage interruptions or voltage breakdowns and also the immediate switch-off of the contactor when the OFF button is pressed.

According to the invention this is achieved in that a normally closed contact of the relay in a branch having a resistor in parallel with the capacitor and to the relay and a break contact of another, directly to the supply voltage connected relay in a connection between the, the relay and the capacitor having, parallel branches is arranged.

This circuit arrangement ensures that this is immediate at the supply voltage connected relays, if this voltage fails, the connection between the two one another parallel branches with the relay and the capacitor closes via its normally closed contact, so that the capacitor is discharged via the relay can and thus the self-holding contact of this relay the holding contact of the contactor bridged for a certain time. Reverses the supply voltage within the set If the time constant does not return, the relay drops out, so that the entire system is de-energized will. If the supply voltage is available and the "Off" button is pressed, this is not possible Contactor as well as the relay from immediately, so that the capacitor via the normally closed contact of the Relay and a resistor is discharged and the circuit arrangement for switching on is available again.

The one directly connected to the supply line is advantageous Relay a capacitor connected in parallel, which is connected to the supply voltage via a break contact ühd via a normally open contact of the relay to a parallel connected resistor is connectable. This parallel connection of the capacitor results in a delayed Activation of the relay has the consequence that when the Supply voltage during self-holding via the relay in the set Time range, the contactor and thus the relay are finally switched off can.

The two relays are advantageously capacitors with a smaller dimension connected in parallel, which are dimensioned in such a way that the relay is kept free of calls will.

An embodiment of the invention is shown in the drawing explained in more detail.

The two bases of the Nteg are denoted by RS, between which the Contactor C has an "on button" and an off button. The contactor C has one Holding contact c, which is parallel to the "On" button. Connected in parallel to contactor C is a relay A, via the series connection of a diode D 1 and one Resistance R 1. The relay A has a normally open contact a 1, which is parallel to the self-holding contact c of the contactor C and is also used for self-holding. Another branch with a capacitor C 1 is parallel to the branch with relay A, which can be charged via the diode D 3 and the resistor R 4. The two branches are connected to one another via a connecting line in which the normally closed contact b 3 of another relay B is located via the diode D 2 and the resistor R 2 is directly connected to the network R S. Between the two branches with the relay A and the capacitor C 1 is parallel to these another Branch with a resistor R 5 and a break contact a 2 of the relay A.

The relay connected directly to the supply voltage B, the capacitor C 3 is connected in parallel via the normally closed contact B 1 of the relay B. In parallel with the capacitor C 3 there is a resistor R 3, namely via a normally open contact b 2 of relay B.

A capacitor C 4, C 2 is connected in parallel to each of the two relays A, B, which are dimensioned in such a way that the relays A, B are kept hum-free during operation are.

The mode of operation of the arrangement is as follows: When switching on the Supply voltage charge the capacitors c 2 C 3 via the resistor R 2 and the diode D 2 on The capacitance of the capacitor C 3 is essential here larger than that of the capacitor G C. As soon as the input voltage of the relay B is reached, this attracts and opens the normally closed contact b 1 and closes the normally open contact b 2. This has the consequence that the capacitor C 3 via the resistor R 3 is discharged. This arrangement ensures that the relay B in the event of failure the supply voltage drops practically instantaneously when the supply voltage returns however, it picks up with a delay.

By pressing button b 2, contactor C picks up and stops via his contact c himself. Also pulls practically without delay the Relay A on, because the capacitor C 4 is dimensioned so that the relay A is just buzz-free is working. The resistor R 1 is only a protective resistor for the diode D 1. When the relay Ä responds, the normally closed contact a 2 opens, so that the Capacitor C 1 cannot discharge through resistor R 5, but rather through the diode D 3 and the resistor R 4 to the peak value of the supply voltage being charged.

When the "off button" b 1 is pressed, contactor C and likewise falls the relay A from practically instantaneous. The normally closed contact a 2 of relay A is now-Ehr closed. so that the capacitor C 1 can discharge through the resistor R 5. This resistor R 5 is dimensioned so that the capacitor C 1 after a few hundredths Seconds is discharged. This means that contactor C is safely switched off.

When the supply voltage fails, relay B practically drops without delay and closes its normally closed contact b 3. This causes relay A to dem charged capacitor C 1 is connected in parallel and remains attracted until the Capacitor C 1 has discharged through relay A. The holding time depends on the Time constants T resulting from the resistance of relay A and the capacitance of the Capacitor C 1 result. Reverses the supply voltage within the Holding time back, the contactor C silver pulls the contact a 1 back on and holds then via contact c itself. Relay B picks up again after a delay, and although after charging the capacitor C 3 and opens its normally closed contact b 3, so that the capacitor C 1 can be fully charged again.

Claims (3)

Patent claims: Electromagnetic contactor with self-holding circuit and undervoltage bridge, which has a relay and a capacitor connected in parallel to the relay, whereby a normally open contact of the relay bridges the self-holding contact of the contactor, characterized in that a break contact (a2) of the relay (A) in a resistor (R5) having branch in parallel with the capacitor (Ci) and the relay (A) and a normally closed contact (b3) of another direct. bar connected to the supply voltage relay (B) in one Connection between the relay (A) and the capacitor (Ci) having, each other arranged parallel branches. 2.) Electromagnetic contactor according to claim 1, characterized in that that the relay (B) connected directly to the supply voltage has a capacitor (C3) is connected in parallel to the supply voltage via a break contact (at) and via a normally open contact (b2) of the relay (B) to a parallel connected one Resistor (R3) can be connected. 3.) Electromagnetic contactor according to claim 1 and / or 2, characterized characterized in that the relays (A, B) each have a further capacitor (4, C2) in parallel.