SU1472957A1 - Contactor drive solenoid with built-in rectifier - Google Patents

Abstract

The invention relates to electrical engineering and can be used in electromagnetic drives of three-pole AC contactors and magnetic starters. The aim of the invention is the expansion of operational capabilities, reduction in weight and size indicators and power consumption. When the control contact 24 is closed, a full-wave electromagnet with windings 17 and 18 is provided. When the auxiliary contact 23 is closed, the electromagnet is supplied with a three-phase voltage for some time before the control contact 24 is opened. When the control contact 24 is opened, the switch to holding mode with the power supply to the winding 18 is performed with a half-wave rectified voltage. 2 hp f-ly, 2 ill.

Description

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The invention relates to electrical engineering and can be used in electromagnetic drives of three-pole AC contactors and magnetic starters.

The aim of the invention is to expand the operational capabilities of reducing the weight and size parameters and power consumption.

Lig.1 shows a control device for an electromagnetic contactor, providing full-wave power to the windings at the beginning of the switching mode; Fig. 2 shows the same, with an additional closing control contact, in which a current flows in each of the windings during a 2/3 period of the power source in the switching mode.

The control unit contains a three-pole contactor, main closing contacts -3, which are connected respectively between the first 4, second 5, third 6 inputs and first 7, second 8, third 9 output terminals. A protection device and a JO load are connected to the output terminals. The electromagnet power supply circuit 1i includes the first 12, the second J3, the third 14, the fourth 15, the fifth 16 terminals, two windings 17 and 18, connected respectively between terminals 12, 14 and 13, 15 in series and opposite in electrical relation, three diodes 19 - 21, the first two of which are connected in parallel to the windings 17 and 18 with the same electrodes to terminals 12 and 13, and the third diode 21 is connected with the same electrode to the common point of the like ends of the windings 17 and 18 and electrodes of the diodes 39 and 20, and the second electrode to 5th terminal 16. Between the first input terminal 4 and 5th terminal. 16 are connected in series with an open control contact 22 and an auxiliary closing contact 23 of the contactor. The first control closing contact 24 is connected between the third terminal 14 and the third input terminal 6.

The device works as follows.

When the closing contact 24 of the control is turned on in one of the half-periods, the current flows from the input terminal 6 through the contact 24, terminal 14, winding 17, the diode 13 to the terminal 5, in

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the next half-period it flows from clamp 5 through terminal 15 of winding 18, terminals 13 and 12, diode 19 to terminal 6, while the current in winding 17 is maintained during this half-period under the action of total self-coupling and mutual induction. Thus, full-wave powering of the electromagnet is realized.

The moving system of the contactor moves from the initial position to the end, the circuit closes the auxiliary contact 23. Before opening the contact 24, windings 17 and 18 of the electromagnet are supplied with three-phase voltage so that a current consumed from the network flows through 2/3 of the period supply voltage, and for 1/3 of the period it is maintained by the total EMF of mutual and self-induction. This provides an increase in traction force developed by an electromagnet and its reliable retraction.

By ensuring that the auxiliary contact 23 is short-circuited before the main contacts 1-3 are closed, it is possible to ensure, from the point of view of durability and retraction reliability, the matching of the contactor and counter forces.

After opening the control hold 24, the winding 38 is energized by a single half-period rectified voltage. The current consumed by the winding 18 from the network flows from terminal 5 through terminal 15, winding 18, the third diode 21, the closed auxiliary contact 23 and the control opening contact 22. In the subsequent half-period, the diode 21 is closed and the current in the winding 18 is closed by diode 13. In this case, the current in the winding 18, which decreases, and the flux in the magnetic system, causes current to flow in the winding 17, which prevents the magnetic flux from decreasing in the system. This helps to reduce the pulsation of the electromagnetic force and to increase its minimum value, which in turn reduces the power required to hold the core in the closed position. The opening of the contactor is accomplished by opening the control contact 22. At the same time stored in

The system emits electromagnetic energy in the form of thermal energy in windings 17 and 18 and partly in diodes 20 and 19, excluding the occurrence of overvoltage. After opening the auxiliary contact 23, contact 22 can be returned to its original position, and the device is ready for a new switch on.

In the device of FIG. 2, a second closing contact 25 of the control operated together with the contact 24 and connected in parallel to the auxiliary contact 24 of the contactor is introduced, which provides three-phase power to the windings 17 and 18 already at the initial turn-on stage and an increase in the degree of force of the electromagnet, and therefore a decrease in its weight and size indicators, or allows the inclusion of an electromagnet with the same winding data with a lower supply voltage. The rest of the device works similarly to the device of figure 1.

Running the winding 17 as a start winding, and winding 18 as a holding in the proposed devices allows providing the necessary MDS in the switching mode and reducing the power consumed by the electromagnet in the holding mode, since the required MDS is holding the multiple holding winding generated from the small wire cross sections are provided: at a lower current consumed from the network.

The proposed device has wider functionality. It allows, within certain limits, to simply increase the tractive force developed by the driving electromagnet, which is necessary in the field of core movement, corresponding to the closure of the main contacts, due to the transfer of the windings to the power supply with a rectified three-phase current. The use of the second control closing contact allows, without altering the winding data of the electromagnet, to turn it on at lower supply voltages or to increase the degree of force, which makes it possible to reduce the weight and dimensions of the contactor. Execution of one winding in the form of start-up, and the other

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in the form of holding, it additionally allows to reduce the power consumed by the driving electromagnet of the contactor.

Claims (3)

1. Drive solenoid contactor with built-in rectifiers,. containing two windings, three diodes, terminals for connecting a three-phase voltage source and control elements, the electromagnet windings being connected in series and oppositely and connected to two terminals for connecting a three-phase voltage source to one directly, and to the other one via a diode is connected in parallel to each of the windings, the diodes are connected by the same electrodes, the point of connection of the electrodes of the diodes is connected to the same electrode of the third diode, the other electrode of which the second control element is connected to the third output for connecting a three-phase voltage source, characterized in that, in order to expand the operational capabilities, the electromagnet is provided with an auxiliary make contact, and the auxiliary make contact, respectively, is used as the first and second control elements contact is connected between the third diode and the second control element. 2. An electromagnet according to claim 1, characterized in that a second control closing contact is inserted in it, connected in parallel with the auxiliary closing contact, the first and second control closing contacts being mechanically interconnected. 3. Electromagnet according to claims 1 or 2, characterized in that, in order to reduce weight and dimensions and power consumption, the winding connected to the first closing control contact is used as a start contact, and the other winding as a holding one. i FIG. 2