DE2749732A1 - Electromagnetic relay with series capacitor - is wound with two wires, insulated from each other and forming capacitor through which winding is energised - Google Patents

Abstract

The relay has a capacitor whose charging current flows through the relay coil when the excitation voltage is switched on. The coil wound with two wires separated by a dielectric. In order to operate the relay the winding start, of one wire and the winding end of the other, electrically separate from the first, wire are connected to the excitation voltage. The number of turns and coil capacitance are such that the ampere-turns necessary for the relay operation are reached for a brief period.

Description

Electromagnetic relay

The invention relates to an electromagnetic relay, its coil cooperates with a capacitor, such that the charging current of the capacitor the coil flows through when the excitation voltage is switched on.

For example, it is known from DAS 2 143 904, the excitation coil to connect a bistable relay in series with a capacitor. When switching the excitation voltage flows through the coil until the capacitor is charged is. The one resulting from the winding resistance and the capacitance of the capacitor The time constant is dimensioned in such a way that it lies within the range of the response time of the relay, so that the flow of current is essentially ended after the relay has responded. A switch is used to switch back the relay, which switches off the excitation voltage and at the same time short-circuits the series circuit of coil and capacitor. Here the capacitor discharges via the excitation coil of the relay.

This assignment of coil and capacitor enables extremely energy-saving Operation of bistable relays, especially since the excitation voltage is only used to respond to the Relay is required, and for switching back the one stored in the capacitor Energy is available.

It is also known from DAS 2 624 913, one with a capacitor to operate a bistable relay connected in series in a monostable manner. Here is a Semiconductor switch connected in parallel for series connection of coil and capacitor controlled in such a way that it is blocked when the excitation voltage is applied and when it is switched off Excitation voltage is conductive. The capacitor will so first of all loaded, whereby the relay responds and is over when there is no excitation voltage the semiconductor switch automatically discharges again, whereby the relay switches back.

It can also be useful to have a monostable relay over a capacitor to be controlled, e.g. if the relay is used as a wiping relay, impulse relay or research relay should be operated.

A suitable control circuit may also be required here.

The control of a relay via a series capacitor has in all the mentioned cases have the advantage of saving control energy. The additional The mostly transistorized circuits required can usually also be economically implemented and set up to save space. In further miniaturization, e.g. the application an integrated design, but the one in series with the relay coil can be used Do not include capacitor.

The invention is based on the object of an electromagnetic To create a relay that can be operated in the manner mentioned, but not one external capacitor is required in series with its coil.

According to the invention this object is achieved in that the coil from two conductors separated from one another by a dielectric is wound that for Operation of the relay one conductor at the beginning of the winding and the other, of which galvanically separate at the end of the winding is connected to the excitation voltage, and that the Number of turns of the coil and the capacity due to the arrangement of the conductors are dimensioned in such a way that the AW value required for the relay to respond is reached briefly.

These measures ensure that the coil that is required anyway also serves as a capacitor. There is no need for an external capacitor which are considerable advantages when setting up a control circuit for the relay in terms of space requirements.

According to one embodiment of the invention it is provided that the conductor material Winding wire is used and the coil is wound bifilar and that the enamel insulation serves as a dielectric.

The advantage here is that the winding technology that has been tried and tested in relay coils is applicable.

A preferred embodiment of the invention is that as Head two mutually insulated metal foils are provided, and that the coil is wound in two layers. One achieves by such a foil winding opposite a bifilar wire winding has significantly higher capacitance values. Considering the coil resistance and inductance result in larger time constants, so that the invention is also applicable to relays with a longer response time.

A further development of the invention is that there is an insulating film Extends over the entire winding width of the coil that several pairs of each other isolated metal foils are arranged parallel to each other and that the beginnings and ends of the metal foils are connected to each other so that the at Switching on the excitation voltage, charging current flowing through the entire coil in the same direction flows through. With only slightly reduced capacity compared to the one described Foil winding is achieved accordingly due to the higher number of turns higher AW value.

According to a further Ausqestaitunq it is particularly advantageous Invention that the beginning of the winding is designed as a conventional coil winding that this winding is separated by one of two by a dielectric Ladders created further winding is added that is the beginning of the operation of the relay the usual coil winding is connected to a terminal of the exciter voltage is, and that the end of the usual coil winding with one conductor at the beginning the other winding and the other, galvanically separated conductor at the end the further winding is connected to the other terminal of the excitation voltage.

At the beginning of the winding, the usual coil winding is used low winding volume achieves high AW values relatively quickly, while the further Winding as a result of the larger winding diameter and the resulting larger Winding length delivers greater capacitance values. The combination of both windings proves thus with regard to the simultaneous achievement of a high AW value as also a large time constant is particularly effective.

Finally, a development of the invention is that the Ohmic component of the resistance of the coil by choosing the layer thickness or the Cross-section of the conductor is set.

Thus, the possibility of influencing is in a simple manner given the electrical time constant of the relay.

6 claims

Claims (6)

Claims 1. Electromagnetic relay, the coil with a Capacitor cooperates in such a way that the charging current of the capacitor passes the coil when the excitation voltage flows through, characterized in that the Coil is wound from two conductors separated from each other by a dielectric, that to operate the relay, one conductor at the beginning of the winding and the other, of it galvanically isolated is connected to the excitation voltage at the end of the winding, and that the number of turns of the coil and the capacity caused by the arrangement of the conductors are dimensioned in such a way that the AW value required for the relay to respond is reached briefly. 2. Electromagnetic relay according to claim 1, characterized in that that winding wire is used as conductor material and the coil is wound bifilar is and that the lacquer insulation serves as a dielectric. 3. Electromagnetic relay according to claim 1, characterized in that that two metal foils isolated from one another are provided as a conductor, and that the coil is wound in two layers. 4. Electromagnetic relay according to claim 3, characterized in that that an insulating film extends over the entire winding width of the coil, that several metal foils isolated from one another in pairs parallel to one another are arranged running, and that the beginnings and ends of the metal foils so with each other are connected that the charging current flowing when the excitation voltage is switched on flows through the entire coil in the same direction. 5. Electromagnetic relay according to claim 1, 3 or 4, characterized in that that the beginning of the winding is designed as a conventional coil winding, that this winding by one created from two conductors separated by a dielectric further winding is added that to operate the relay the beginning of the usual Coil winding is connected to a terminal of the excitation voltage, and that the End of the usual coil winding with one conductor at the beginning of the further winding and the other, galvanically separated conductor at the end of the further winding is connected to the other terminal of the excitation voltage. 6. Electromagnetic relay according to claim 3 and 5, characterized in that that the ohmic part of the resistance of the coil by choosing the layer thickness or the cross-section of the conductor is specified.