DE550869C - Alternating current electromagnet, in which a choke is switched on in the circuit of its magnet winding - Google Patents

Description

AC electromagnet with its magnet winding in the circuit A choke is switched on. Alternating current electromagnets often have to be designed in this way be that they can be used for voltages of different levels, often in a range from i: i o include, can be used. In the known arrangements, the magnet designed in such a way that it has the required ampere-turns at the lowest voltage owns. However, if the highest voltages occur during operation, show face all kinds of ills. The magnetic forces become so great that they become mechanical Cause damage to the facilities; also the currents that the magnet can reach values that can only be achieved with great difficulty with the help of relay contacts can be switched.

It has now been proposed to reduce an excessive rise of the current when the voltage rises, iron-en-hydrogen resistors in front of the magnet winding to switch. -The regulation range for voltage fluctuations of the occurring magnitude but is far from sufficient.

In other facilities, special regulating devices, e.g. B. Choke coils with a movable core are provided. Such devices are but relatively expensive, moreover, their moving parts do not ensure a safe way of working under all circumstances. Therefore, choke coils are movable Core, especially for small electromagnets, such as those used for. B. are used in relays, not applicable.

Arrangements are also already known in which the magnet is connected to the secondary circuit of a highly saturated transformer whose Primary winding in series with a non-saturated choke on the line voltage lies. In these arrangements, the magnet is supposed to be of a high level Degree of saturation of voltage fluctuations fed into a transformer that is as independent as possible will. Such transformers are only relative to a certain extent small range of tension regardless of its size. They also require a relatively high expenditure of active iron material and windings, even if part of the alternating current magnet itself is a saturated alternating current consumer serves.

The disadvantages of the known arrangements are in an alternating current electromagnet, in which a choke is switched on in the circuit of its magnet winding, eliminated according to the invention in that the connected in parallel to the magnet winding Choke a core made of a material of high 'initial permeability and lower Has maximum induction and together with the magnet winding in series to form an ohmic or inductive resistance. Such chokes with a core made of a material with high initial permeability and low maximum induction, for example from a nickel-iron alloy are known per se.

In Fig. I an # embodiment of the invention is shown. One Magnet M is connected to a throttle D in parallel. Both are over a resistance W and a switch i connected to the network. Instead of a switch i, a switch can also be used z be provided so that it allows the separation of the magnet M only from the network. The core of the magnet M is made of ordinary iron, while the core of the Choke D consists of a nickel-iron alloy.

The mode of operation of the arrangement is based on the difference in the magnetization curves of both cores. The magnetization curve of a nickel-iron alloy shown in Fig. Z differs from the magnetization curve of a normal one shown in Fig Magnetic iron due to a higher initial permeability and a far lower maximum induction. The high initial permeability of the nickel-iron alloy causes the throttling effect the choke D grows proportionally with the voltage at low voltage values. From a relatively low value of the voltage, however, the throttling effect increases due to the low maximum induction of the alloy no longer proportionally with the tension, but it remains almost constant. This ensures that at with increasing voltage, an ever larger part of the total current through the choke flows and not through the magnet. The current flowing through the magnet becomes fluctuate to a much lesser extent than the voltage of the network. Also asked the Device has the advantage that the small currents occurring at low voltage sufficient to operate the magnet due to the high initial permeability of the core, so that even the at. voltage still remaining after a mains short circuit of the magnet. The device is therefore particularly suitable for trip magnets suitable for switches and eliminates the need for a special auxiliary battery.

By changing the core cross-section and the ampere turns of the Choke D can be the point from which to its maximum induction one on the magnet Exerts current-limiting effect, can be set within wide limits. Instead of of the ohmic series resistor W can also be an inductive series resistor be used. This inductive resistor is expedient to be designed in such a way that its voltage drop increases as quickly as possible with the voltage, d. H. that be The core has a high initial permeability, but without the voltage increases that occur to get into the area of saturation. This can be achieved with a throttle with a core of silicon alloyed iron, which is within the occurring magnetization range is not saturated.

With regard to the lowest possible energy consumption, you will generally provide a switch at position i. On the other hand, it depends on a lot If the switches are not subject to a low load, they will be arranged at point z and the current flowing through the series resistor and the choke is permanent permit.

Claims (5)

PATENT CLAIMS: i. AC electromagnet, in which a choke is connected in the circuit of its magnetic winding, characterized in that the choke connected in parallel to the magnetic winding has a core made of a material of high initial permeability and low maximum induction and, together with the magnetic winding, is in series with an ohmic or inductive resistance . 2. AC electromagnet according to claim i, characterized in that the magnet winding a choke with a core made of a nickel-iron alloy connected in parallel and an ohmic or inductive resistor is connected upstream of both windings. 3. AC electromagnet according to claim i and z, characterized in that the two parallel windings an inductive resistor, its voltage drop increases as much as possible with increasing current strength, is connected upstream. q .. AC electromagnet according to claim i to 3, characterized in that the two parallel windings a choke with a core made of a silicon-iron alloy is connected upstream. 5. AC electromagnet according to claim i to q., Characterized in that when switching off only the winding of the electromagnet is de-energized.