DE935073C - Device for discontinuous voltage control, especially for airfield lighting - Google Patents

Description

ISSUED NOVEMBER 10, 1955

X 7536 VIII c12if

There are devices, especially for airfield lighting, that contain a voltage divider, dei 'connected to a supply voltage source and the one with a number of taps for taking different voltages is provided, each of which is actuated by a separate electromagnetic relay Switch can be connected to the load, the excitation winding of each relay via a separate actuation switch with an alternating voltage source can be connected.

For example, if the exposure is airfield lighting, it is that way possible, depending on the weather, e.g. B. Xebel, rain, bright weather, etc., one more or to achieve less strong lighting of the airfield. As a result of the closing of one of the operating switches of the excitation windings responds to the respective relay, and the one coupled to it Switch closes, whereby the selected tap of the voltage divider, which a given voltage has to be connected to the lighting. In this case, when another actuating switch of another field winding is closed should be - in order to apply a different voltage to the load - the first switch that the selected tap connects to the load, must necessarily be open, otherwise in a part of the voltage divider short circuit would occur. The fact that the operating switch of the former Excitation winding opens before another operating switch closes, gives in

In this case there is still no adequate guarantee against the short circuit mentioned, since the combination is of the armature and the switch actuated by the relay, which is no longer energized, stick can, so that the load remains connected to the relevant tap.

According to the invention, this drawback is remedied in that in a device of the be wrote a common feed line ίο after the AC voltage source the series connection contains an inductance and a capacitance, which are dimensioned such that the series connection is at least nearly in resonance at the frequency of the alternating voltage, and furthermore each electromagnetic relay is provided with an auxiliary contact, which in the addressed state of the Relay short-circuits the capacitor, if necessary via a resistor.

The invention is based on the knowledge that the impedance of the excitation winding of a Relay in the unresponsive state, so with an open armature, generally significant, z. B. is ten times lower than in the mentioned condition with the anchor tightened. Under "almost in resonance" is to be understood here as essential that the series connection absorbs such a part of the alternating voltage that the residual voltage on the respective excitation winding sufficient to respond to the relay, while after a short circuit of the capacitor the Inductance absorbs such a part of the alternating voltage that when another actuating switch is closed, the voltage at the now connected excitation winding with the armature of the relay open is not to ' speaking of the relay is sufficient.

According to a further feature of the invention, the impedance corresponds to the inductance mentioned at least approximately that of each of the excitation windings in the non-addressed condition of the relay.

The invention is explained in more detail below with reference to the schematic drawing, for example.

An AC voltage source is connected to the transformer 2, its secondary winding 3 is provided with taps 4, 5 and 6 and thus serves as a voltage divider. The taps 4, 5 and 6 can be used with the load, for example airfield lighting, via switches 7, 8 and 9 10, to be connected.

The switches 7, 8 and 9 are connected to the armatures 11, 12 and 13 of the electromagnetic relays 14, 15 and 16 coupled, the excitation windings 17, 18 and 19 via separate actuating switches 20, 21 or 22 with a terminal of the alternating voltage source 1 can be connected.

The other ends of the excitation windings 17, 18 and 19 are according to the invention via the series connection of an inductance 23 and a capacitance connected to the other terminal of the AC voltage source. Furthermore are the relays provided with auxiliary contacts 25, 26 and 27, which in the addressed state of the respective relay, z. B. of the relay 14, the capacitor 24 short-circuit. The inductance 23 and the capacitance 24 are such dimensioned that their series connection more or less in resonance with the frequency of the AC network 1 is.

In the position shown, the switch 20 is closed, the excitation winding 17 still via the series connection of the inductance 23 and the Capacity 24 is fed because the auxiliary contact 25 before the relay 14 responds, that is, when it has dropped out Anchoring, is still open. Since the series connection is in resonance, the excitation winding receives 17, apart from the ohmic voltage loss in the series circuit, approximately the full AC voltage is supplied, and the relay 14 responds. As a result, close the switch 7, and the auxiliary contact 25, as shown, and the load 10 is at the lowest Voltage connected, the capacitor 24 being short-circuited.

It is assumed, for example, that the impedance of each field winding 17, 18 and 19 is approximately 100 ohms when the armature is open and approximately 1000 ohms when the armature is closed. If the impedance of the inductance 23 is, for example, also 100 ohms, the alternating voltage at the excitation winding 17 after the capacitor 24 has been short- ^{circuited is approximately 100} % ioo = ¹⁰ Ai part of the full line voltage.

If the switch 21 now closes, the excitation winding 18 receives voltage via the inductance 23 supplied. Since the armature 12 is still open, the winding 18 has an impedance of 100 ohms, similar to inductance 23, so that the voltage on winding 18 is only half the mains voltage, whereby the relay 15 can not respond. That way is the Device thus before short circuit of the lying between the taps of the secondary winding 3 Part secured.

Even when switch 20 is open and armature 11 sticks, the device is short-circuit free.

It should also be mentioned that the voltage source to which the voltage divider 3 is connected can also be a DC voltage source.

Finally, the device according to the invention can also be used for airport lighting other suitable loads are used, although the former with consideration of the high requirements the operational safety and security for the airfield as well as the proportionate great power and the large distances, which makes the use of relays, mostly with Remote actuation, required, is particularly suitable. iao

Claims (2)

PATENT CLAIMS: I. Device for discontinuous voltage control, especially for airfield lighting, with a voltage divider connected to a supply Voltage source can be connected and the one with a number of taps for Withdrawal of different voltages is provided, each of which has a separate, depending on the means an electromagnetic relay operated switch to be connected to the load can, whereby the excitation winding of each relay has a separate operating switch with a supply voltage alternating source can be connected, characterized in that a common feed line after the AC voltage source, the series connection of an inductance and a capacitance contains, which are dimensioned such that the series connection at the frequency of the AC voltage is at least nearly in resonance and furthermore each electromagnetic relay with an auxiliary contact is provided, which in the activated state of the relay, the capacitor, possibly via a resistor, short-circuits. 2. Apparatus according to claim 1, characterized in that the impedance of the inductance corresponds at least approximately to that of each of the excitation windings in the non-addressed state of the relay. 1 sheet of drawings © 509 571 11.55