DD210502A1 - CIRCUIT ARRANGEMENT FOR CIRCUIT AND DEMAGNETIZATION OF DC-ELECTRICITY ELECTROMAGNETS - Google Patents

Abstract

The invention relates to a circuit arrangement for magnetizing DC-powered electromagnets as well as their demagnetization means of the resulting after switching off the magnetizing current in the electromagnetic coil self-induction current. Characteristic of this circuit arrangement is that the coil of the electromagnet are two polarized, connected in series by connecting poles of the same series capacitors; that the two capacitors each have a diode connected in parallel in the reverse direction; that the magnetization voltage via the diode connected in the flow direction auflaedt one of the two capacitors, thereby avoiding that caused by the elimination of the magnetizing current in the coil of the electromagnet self-induction current, which is opposite to the polarity of the capacitor in question, damaging the capacitor; the electrical energy produced by self-induction after elimination of the magnetizing current in the coil of the electromagnet charges the capacitors connected in parallel and balances their voltage; these capacitors provide a very low resistance to the self-induction voltage and thus cause a strong demagnetizing current in the coil of the electromagnet.

Description

Berlin, January 20, 1983 61 298/17

 Circuit arrangement for the switching and demagnetization of Gleichstromompegeeate electromagnet

Field of application of the invention

The invention relates to a circuit arrangement for the switching of Gleichatromgespeiaten electromagnets, in particular of high-performance electromagnets, as well as their demagnetization by means of their own Selbstinduktionsatroms,

Characteristic of the known technical solutions

It is already known from US Pat. No. 2,445,459 that an effective, automatic and complete demagnetization of the electromagnet takes place with the aid of an unpoled capacitor connected in parallel with the coil of the electromagnet when the magnetization pulse is switched off. However, the relatively large space requirement of reversed capacitors z is disadvantageous. In switching devices for high power electromagnets ·

Aim of the invention;

The aim of the invention is to reduce this large space requirement.

Presentation of the invention of the invention

The invention has for its object to provide a circuit arrangement that allows relatively small

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poled capacitors, Elektr · B. electrolytic capacitor ^ in the circuit and demagnetization of various DC-powered electromagnets by means of self-induction current - to use even of high-performance electromagnets suitable circuits.

This object is achieved in that the coil of the electromagnet are connected in parallel to each other in series capacitors, that the two capacitors each one or the one capacitor is connected in parallel with a diode and that the operating switch is located in the magnetizing circuit. As capacitors also reversed capacitors can be used. When electrolytic capacitors are used, the electrolytic capacitors connected in parallel to the coil of the electromagnet are connected in series by connecting two poles of the same name, and a reverse-polarity diode is connected in parallel to each of the two electrolytic capacitors. When using electrolytic capacitors is characteristic of the circuit arrangement according to the invention that the diodes mentioned prevent together with the resulting charges in the electrolytic capacitors that charge the electrolytic capacitors under the action of magnetization and self-induction of their own polarity opposite, but that of the self-induction in the coil of the Electromagnet caused demagnetizing current only increases the charge of one electrolytic capacitor and partially overrides the other.

When unpoled capacitors are used, it may also be expedient to use only one of the two capacitors.

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(G or Cp) a diode is connected in parallel

It may also be advantageous that one capacitor (G ₁ or Cp) is poled and the other is unpaved.

The operating switch (K) can be designed as a contact switch,! Transistor, thyristor or as another suitable current switch.

AusfuhrangabeisρieI

In the following, with reference to the accompanying drawings, the puncture of the circuit arrangement according to the invention will be described in more detail. Show it:

Pig. 1: the circuit arrangement in a version with two diodes;

Pig.ia: a functionally equivalent to the above circuit;

Pig. 2: the circuit order in a version with a diode;

Pig, 2a: a functionally equivalent to the above circuit;

Pig · 3> 4 and 5: the aur Pig. 1 belonging voltage / time curves «

Tir'enn the one in Pig. 1 shown circuit 1 is closed with the switch K, the voltage U starts

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Stromquelle'VL at the poles of the sink L of the electromagnet M to act (Pig 3: T ₁ -T ₂ ), the current flowing through the coil L magnetizes the electromagnet M, the electrolytic capacitor G. charges via the diode D ₁ au a voltage which is higher than that of the current source VL (Fig _o : T ₁ -T ₂ ), and the electrolytic capacitor G ₂ charges under the influence of the pulsating direct current through the diode D ₂ ^{to ο} ^ ^ηθΓ voltage lower is as that of the power source. "VL (Fig. 5: I ₁ -T ₂ ) When the circuit 1 is interrupted with the switch E, the energy of the electromagnetic field discharges, and at the coil L of the electromagnet M one of the poles FIG. 3: T ₂ -T ₃ ), which increases the charge of the electrolytic capacitor G ₂ via the diode D ₂ and the electrolytic capacitor G ₁ (Pig. 4: T ₂ -TO and in FIG Coil L of the electromagnet M "a magnetization trom opposite current - a Demagnetisierungs3trom - generated.

Because of its resistance in the direction of the dip, the diode D _{2 is} able to prevent the effect of the demagnetizing current on the charge of the electrolytic capacitor G ₁ au, but this charge is partially removed by the demagnetization current (Pig. 4: T ₂ -T-). After demagnetization remain in the electrolytic capacitors G ₁ and C ₂ equal charges (Pig · 4 and 5s T ₅ -T ₄ ) · In cases where the charge generated in the electrolytic capacitor G ₁ is sufficiently large, a functionally equivalent result can also without achieving the diode D (Figure 2). Depending on the application, the pattern in the circuits (Figure 1 Ia _3. 2a) located electrolytic capacitors G ₁ and G ₂ - corresponds

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neither both or one of them - be replaced by unpolished capacitors. As the operating switch K of the circuit come a contact switch, a transistor, a thyristor or another power switch in embossing.

The above-described circuit arrangement is suitable for switching and demagnetizing various DC-powered inductances, in particular electromagnets.

Claims (5)

a sm -6- 20.1.1983 61 293/17 Inventory 1. circuit arrangement for switching DC-powered inductances, in particular of electromagnets, and for their demagnetization by means of the current generated by self-induction, characterized in that the coil (L) of the electromagnet (M) two capacitors standing in series to each other (G ₁ , C ₉ ) are connected in parallel and that the two capacitors (C, G ₂ ) each have a diode (D ₁ , D ₂ ) or only the one capacitor (G) a diode (D ₁ ) is connected in parallel and that the operating switch (K) in Magnetizing circuit (1) is located. 2 · Circuit arrangement according to item 1, characterized in that the capacitors (G., G ₂ ) are poled capacitors, which are series-connected by connecting two poles of the same name, and in that the two capacitors {Q ^, Q ^) each have a diode in the reverse direction (D., D ₂ ) is connected in parallel 3. Circuit arrangement according to item 2, characterized in that only one of the two capacitors (G ₂ ) a diode in the reverse direction (D ₁ ) is connected in parallel "is <, 4a circuit arrangement according to point 1, characterized in that both capacitors (G ₁ , G ₂ ) are unpoled capacitors · 5. Circuit arrangement according to item 4 », characterized in that only one of the two capacitors (G ₁ or G ₂ ), a diode is connected in parallel. -7- 20.1.1983 61 298/17 6. Circuit arrangement according to item 1, characterized in that one capacitor (G ₁ or Cp) is polarized and the other is unpoled, 7. Circuit arrangement according to item 1, characterized in that the operating switch (K) is a contact switch, a transistor, a thyristor "or another suitable current switch. - For this 3 pages drawings -