DE176430C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

■■ -Yes 176430 CLASS 21 c. GROUP

in Berlin.

The present invention is an automatic switch to avoid the No-load losses in transformers that work in parallel with others on a common Secondary network work. The advantages of the same lie besides in its simplicity and Operational safety in the manner in which it responds to voltage fluctuations emanating from the primary network.

ίο The essence of the invention is that the switch is under the influence of a Voltage relay is on and also on switching off by one with the transformer series-connected electromagnet is prevented as long as the current supply of the transformer exceeds a certain value. The mode of action should be based on the one shown in the drawing Embodiment are explained.

t is, for example, single-phase transformer which together operate in parallel with at least one other transformer as well as the current load of the secondary network is not marked on the latter, s, which einbezw both primary and secondary automatically switch the transformer according to the load. turns off. The one resp. Disconnection is. In the illustrated embodiments by a respectively fed from the secondary network solenoid e respectively. α brought about, which act on a common iron core connected to the switch. The two solenoids are switched over by a voltage relay b with a maximum or Minimum contacts a ¹ resp. e ¹ , to which α respectively. e is connected. A current relay c with minimum contact k is also provided. The excitation coil of the relay c is in rethe with the transformer t, the contact k is in series with those of the voltage relay.

The mode of operation is as follows: there is initially little or no load and the transformer is switched off accordingly. In this case the secondary voltage is high, relay b is connected to contact α ^l and relay c is connected to contact k. If the load increases, the secondary voltage drops, the relay b changes over to e ¹ , and since k is closed, the solenoid e is excited and switches on the transformer. This now takes over part of the load, which causes contact k of the current relay to open. If the load later falls below a certain value again, k closes, while b is ^{transferred to α 1} as a result of the increasing secondary voltage; the switch is turned off again.

If one examines the influence of which fluctuations in the primary voltage (originating from of load fluctuations in other secondary networks, of changes the voltage of the control center, etc.) have on the device described, so you can see the following: The transformer is switched on when the load increases as a result of the the resulting decrease in the secondary voltage. The latter would also decrease with

the primary voltage occur. In this case, too, the transformer would be switched on, since b would be transferred to e ^l and k is closed. The connection is desirable as this prevents the connected lamps from burning too dark. The transformer is switched off when the load decreases as a result of the increase in the

ίο secondary voltage. The latter would also occur with increasing primary voltage. In this case, however, the transformer is not switched off, since b is transferred to a ¹ , but k is open, so the solenoid α can not receive any current (this point in time is based on the drawing). The fact that the transformer is not switched off in this case despite the higher secondary voltage is a great advantage since the fuses of the other transformers working in parallel could easily blow if one is switched off despite the existing load. As you can see, the switch described responds to a falling primary voltage when the transformer is switched on, but not to a rising primary voltage when it is switched off.

It should be noted that transformer switches with voltage and current relays are already known are. However, the latter was previously connected in series with the load or with a continuously switched on transformer. It must then be in the immediate vicinity of the transformer to be switched on and off a second respectively. stand a specially arranged auxiliary transformer. In the arrangement described, the Transformer stand as far away from everyone else. The current relay works because it is in series with the transformer, only when it is switched on, thus only has an influence on the elimination, being the same depending on the load prevents or allows. The fluctuations in the current intensity of the secondary network have no direct influence on the connection, but only an indirect one due to the voltage fluctuations that they cause.

It is appropriate that the solenoids a respectively. e can be switched off again each time after the switch s has been adjusted, because this saves power losses and the solenoids can be made weaker; In addition, this protects the relay contacts, as they then never have to interrupt a current. The solenoid e automatically switches off through the interruption point d, which is bridged by the switch s as long as it is switched off, but is interrupted when it is switched on. The solenoid α is switched off in that its second connection point is selected in the transformer line between the winding and the interruption point of the switch s .

In the case of three-phase transformers, it is sufficient to switch one phase in the manner shown Adjustment of the switch to use.

Modifications to this device are also possible, which apparently have no advantages over this embodiment. So could z. B. instead of a common voltage relay with maximum and minimum contact, the lines of the two solenoids α and e are routed via a special mechanically independent voltage relay, one of which has only a maximum contact and the other only a minimum contact. If, however, they are not both precisely adjusted or if disturbances occur, then both relays could be closed at the same time; this would cause the switch s to oscillate when the load is low.

Claims (1)

Patent claim: Switching arrangement to avoid the no-load work of transformers which work on a common secondary network, consisting of an electromagnetic on and off switch dependent on a minimum current relay and a voltage relay, characterized in that the minimum current relay (c) is in series with the transformer to be switched off or on and that the contact levers of both relays (b and c) are connected in series, for the purpose of switching off the transformer only when the consumption current decreases and switching on only-free decrease in the voltage at the point of consumption. 1 sheet of drawings.