NL8203232A - COUPLING DEVICE FOR COUPLING AND MAGNETIZING DC-POWERED ELECTROMAGNETS. - Google Patents

Description

* * νο 3663 in Κορρelin g ing for coupling and demagnetizing DC powered electromagnets.

The invention relates to a coupling device for coupling DC-powered electromagnets, in particular electromagnets of. large capacity, as well as · demagnetization thereof by means of its own self-induction current.

It is already known from United States Patent Specification 2Λ1 + 5Λ59 that effective, automatic and complete demagnetization can be achieved by means of a capacitor which is connected in parallel with a winding of the electromagnet by switching off the magnetizing current to the winding. However, the device described in this patent has the disadvantage that the non-polarized capacitors. with the required large capacity have a large size, and thus are bulky as well as expensive, for example when used in connection with coupling devices with large capacity electromagnets.

The object of the invention is therefore to provide a new and improved coupling device, which enables the use of polarized capacitors of a relatively small construction size, for example electrolytic capacitors, as components in suitable circuits for coupling and demagnetizing DC-powered electromagnets, especially large-capacity electromagnets.

The method according to the invention is characterized in that two capacitors in series with each other are connected in parallel with the winding of the electromagnet, a diode is connected in parallel with. The two or with one of the capacitors, and the switch is located in the magnetizing circuit. Even non-polar capacitors can be used. When electrolytic capacitors are used, the method is characterized in that the electrolytic capacitors connected in parallel with the winding of the electromagnet are in series 30 so that equal poles thereof are connected to each other, and a reversing diode is connected in parallel with the two or one of the electrolytic capacitors. When electrolytic capacitors are used, the method is characterized in that the diodes together with the charges which have taken place in the electrolytic capacitors prevent the capacitors from being charged to a voltage which is reversed to their polarity below the polarity of the capacitors. influence of the energizing and self-induction voltages, as a result of which the demagnetizing current caused by the self-induction voltage in the winding of the electromagnet increases the voltage in one electrolytic capacitor and cancels it in the other.

The invention is further elucidated with reference to the drawing, in which:

Fig. 1 shows a circuit with two diodes for application of the method.

Fig. 1a shows a circuit, the operation of which corresponds to that of Fig. 1, Fig. 2 shows a chain with a diode for application of the method, Fig. 2a shows a circuit, the operation of which corresponds to that of Fig. 2. 2, and FIGS. 3-5 show voltage / time graphs relative to FIG. 1.

When the circuit 1 shown in Fig. 1 is closed with a switch 20 K, the voltage of the current source VL influences the poles of the winding L of the electromagnet M (Fig. 3, - Tg), magnetizes the winding While the electromagnet M is current, the electrolytic capacitor is charged via the diode D ^ to a voltage higher than that of the current source VL (FIG. U, - Tg) and the electrolytic capacitor Cg is charged under the influence of a pulsating direct current through the diode Dg to a voltage lower than that of the current source (VL) (Fig. 5, T ^ - Tg) · When the circuit 1 is switched off with the switch K, the energy of the electromagnetic field discharged, so that in the winding L of the electromagnets M a self-induction voltage is generated with a polarity opposite to the voltage of the current source VL (Fig. 3, Tg - T ^), which is the charge in the electrolytic capacitor Cg via the diode Dg and the electrolytic cond ensator raises (fig. b, Tg - T ^) and in the winding L of the electromagnet M causes a current reversal with respect to the magnetizing current, i.e. a demagnetizing current.

Due to the resistance in the conductive direction, 820 3 2 32 ".............. '' ...........

# · 1 »3 3can.the diode Dg does not prevent the distribution of the demagnetizing current to the charge in the electrolytic capacitor, but the charge is partially canceled thereby (Fig. 4, Tg - T ^). When de-magnetization has taken place, equal charges remain in the electrolytic capacitors C1 and Cg (FIGS. 4 and 5, ~). In cases where the charge in the electrolytic capacitor is sufficiently high, the same operation can be achieved even without the diode Dg (Fig. 2). Depending on the end use, can. the electrolytic capacitors C1 and Cg, i.e. one or both, in the circuits shown in Figs. 1, 1a, 2, 2a, 10 are replaced by non-polar capacitors. The switch K of. the circuit may be a contact switch, a transistor. tor, a thyristor or any other type of switch.

The disclosed disclosure is suitable for coupling and demagnetizing various inductances, in particular DC powered electromagnets.

8203232

Claims (5)

Method for coupling and demagnetizing DC-powered inductances, in the absence of electromagnets, the current being produced by self-inductance, characterized in that two capacitors (C ^, Cg) connected in series are parallel-5 slates connected with a winding (h) of an electromagnet (M), a diode (D ^, Dg) being connected in parallel with each capacitor, a diode (D ^) being connected in parallel with a capacitor (Cg), and a control switch (K) is located in a magnetizing chain (1). Method according to claim 1, characterized in that the capacitors (C ^, Cg) are polar capacitors connected in series such that equal poles are connected to each other, a diode (D ^, Dg) having not Conductive direction is connected in parallel with each capacitor. Method according to claim 2, characterized in that a. diode (D.j) with non-conductive direction is connected in parallel with a capacitor (Cg). i *. Method according to claim 1, characterized in that both capacitors (C 1, C 8) are non-polar. 5. Method according to claim k, characterized in that a diode is connected in parallel with a capacitor (C 1 or C 8). A method according to claim 1, characterized in that one of the capacitors (C 1 or C 3) is polar and the other non-polar. Method according to claim 1, characterized in that the switch (K) is a contact switch, a transistor, a thyristor or another suitable type of switch. 8203232