SU763997A1 - Thermomagnetic relay - Google Patents

Description

(54) THERMOMAGNETIC RELAY

I

The invention relates to a technique for measuring temperature, in particular, a relay serving to monitor and signal thermal processes, and can be used to automatically control, control, protect and signal various thermal processes.

Thermomagnetic relays are known that contain a magnetically controlled contact and a thermomagnetic element 1.

The disadvantage of such a device is the impossibility of adjusting the response differential (deadband).

Closest to the invention is a thermomagnetic relay containing a magnetically controlled contact, two permanent magnets, between which the thermomagnetic element 2.i is placed

The known relay also does not allow the trigger differential to be adjusted and sensitivity to be increased.

The purpose of the invention is to eliminate these disadvantages.

This goal is achieved by the fact that the thermomagnetic relay is provided with a control winding and an adjustable resistor, with one end of said control winding

It is connected to a magnetically controlled contact, and the other to an adjustable resistor.

The drawing schematically shows

 proposed device.

5 The thermomagnetic relay consists of a switching magnetic contact 1, the electrodes 2 and 3 of which are normally closed, the electrode 2 is not ferromagnetic, but the electrodes 3 and 4 are ferromagnetic. In the contact overlap zone, there is a thermo-magnetic element 5, at the ends of which there are permanent magnets 6 and 7. The control winding 8 is placed on the flask of the magnetically controlled contact 1, which is connected to the power supply through the closing contacts and an adjustable resistor 9.

At temperatures below the Curie point of the thermomagnetic element 5, the magnetic flux generated by the permanent magnets 6 and 7 is closed through the thermomagnetic element 5

20 and the ferromagnetic electrodes 3 and 4 of the magnetically controlled contact 1. Under the action of the magnetic field, the middle 3 and the side 4 ferromagnetic electrodes are closed. A current flows through the winding 8 of the relay, creating a magnetic field opposite to the direction of the field of the permanent magnets 6 and 7. The current is set using an alternating resistor 9 such that the resulting field keeps the electrodes 3 and 4 in a closed state.

When the ambient or controlled object temperature increases, the thermomagnetic element 5 loses its ferromagnetic properties, increasing the magnetic resistance for the flux created by the permanent magnets 6 and 7. The magnitude of the resulting magnetic field decreases and is insufficient to keep the electrodes 3 and 4 in a closed state. Under the action of the elastic force, the middle electrode 4 moves towards the non-magnetic electrode 2, thereby disconnecting the winding 8 of the relay. The magnetic flux closing through the electrodes 3 and 4 increases sharply (by the amount of compensated flux by the winding 8), but will not be sufficient to close the electrodes 3 and 4.

When the ambient or controlled object temperature decreases, the thermomagnetic element 5 increases its conductivity and the magnitude of the magnetic flux generated by the permanent magnets 6 and 7 is sufficient to close the electrodes 3 and 4.

Thus, by changing the amount of current flowing through the winding 8 by an adjustable resistor 9 or by changing the number of turns of the winding 8 (by drawing conclusions through a certain number of turns-), the switching temperature of the relay can be changed, while the return temperature remains independent characteristic of thermomagnetic alloy.

The condition of the reverse-response temperature (lower temperature limit) when the forward response temperature changes (upper temperature limit) makes it possible to adjust the differential (deadband) of the relay by changing the response temperature.

If it is required to have a constant (not adjustable) direct response temperature, and adjust the relay differential by changing the reverse response temperature, it is necessary to connect winding 8 to electrode 2 so that the magnetic field created by the winding is directed according to the magnetic field of the permanent magnets. and 7.

By setting the current flowing through the siphoning of the relay, corresponding to the value, you can set the relay so that it reacts to a slight temperature change, i.e., the relay will be more sensitive to temperature change. In addition, the relay reacts to the direction of the switched current, when the relay changes polarity, the flows created by the permanent magnets 6 and 7

and winding 8, are summed up, and the relay does not respond to temperature changes.

By changing the current in the winding 8, you can change the magnetic field and, in turn, vary the location of the transition point on the steep part of the temperature dependence curve of the thermomagnetic element 5 and thereby the relay triggering parameters.

The use of the invention allows to significantly expand the functionality of thermal relays, since the proposed thermal relay reacts not only to temperature changes, but also to the direction of the switched current, and is highly sensitive to changes in the temperature of the environment or the object being monitored. The proposed device allows the relay differential to be controlled by varying the upper and lower limits of temperatures at a constant lower or upper limit of temperatures, respectively.

Claims (2)

Invention Formula A thermomagnetic relay containing a magnetically controlled contact, two permanent magnets, between which a thermomagnetic element is placed, is characterized in that, in order to control the differential and increase the sensitivity, it is equipped with a control winding and an adjustable resistor, one end of said control winding being connected to a magnetic control kontakom, and the other - with an adjustable resistor. Sources of information taken into account in the examination 1. US patent number 3812441, cl. H 01 H 37/08, 1975. 2. Patent of Great Britain No. 1452304, cl. H 01 H 37/58, 1977.  l  . . one F I -eight / five rt