SU993353A1 - Thermal relay - Google Patents

Description

The invention relates to electrical engineering, namely, temperature-sensitive devices for controlling thermal conditions.

Thermal relays are known for controlling temperature regimes consisting of a magnetic circuit having a portion of a thermomagnetic material with a Curie point equal to the controlled temperature 1.

The disadvantage of the thermal relay data is that when the temperature changes near the Curie point, the magnetic magnitude of the thermomagnetic element does not change quickly enough (in the range of several tens of degrees), which leads to a low accuracy of matching the temperature of the device

The closest in technical essence to the present invention is a thermal relay containing two permanent magnets, a contact group and a temperature-sensitive element 2.

The disadvantage of this thermal relay is the low reliability of operation due to the influence of the fields of the permanent magnets, as well as the complexity of the design. .

The purpose of the invention is to increase the reliability of operation and simplify the design. :

The goal is achieved by the fact that the permanent magnets are set so that their magnetization axes lie on one straight line and form the specified contact group, one of the permanent magnets is made of ferromagnetic material, for example, of an intermetallic compound having the property to change direction magnetization on the opposite with a change in temperature and coercive force H 7VJ + HO, where N is the magnetisation factor of the magnet; D-magnetization of the magnet in the. Band

relay operation temperatures; H „- field external sources.

20

FIG. 1 shows the design of the proposed thermal relay; in fig. 2 - temperature dependence of the residual magnetization of a permanent magnet made of an intermetallic compound, where T is the temperature of compensation of magnetic moments, the sublattices of a ferromagnet.

The thermostat consists of constant

30 magnets 1 and 2, the last of which

made of ferromagnetic material (inversion). Both magnets 1 and 2 are attached to elastic plate-conductors 3 and are widely used in the contact groups of electromagnetic devices. When the temperature of the medium is higher than the inversion temperature of the magnet 2, the direction of magnetization of the permanent magnet 1 is opposite to the direction of magnetization of the inversion magnet 2 and the contact is open.

It should be noted that the feature of a permanent magnet made of a ferromagnetic material is that at the rate of compensation of the magnetic moments of the sublattices of the ferromagnet, the magnetization changes direction to the opposite, i.e. the magnetic field of the magnet is inverted. In order that the dependence of the residual magnetization on temperature corresponds to that shown in FIG. 2, a sample of a ferromagnet must have a coercive force of no less than a demagnetizing field acting on it (the demagnetizing field acting on the magnet is made up of the actual demagnetizing field of the magnet, which depends on its geometry and magnetization, and the field of external sources) Such a temperature dependence of the residual magnetization in a wide temperature range was first discovered in the alloy of the intermetallic compound tulli and cobalt, and permanent magnets Ita this trip received the call invesionnymi ..

Thermo relay works as follows.

When the temperature decreases below T of the inversion magnet 2, the direction of magnetization changes to the opposite one in it and the permanent magnets are attracted to each other, thus the contacts are closed. As the temperature of the medium rises above the TC of the inversion magnet 2, magnetization inverts in it and the magnets repel each other. The permanent magnets 1 and 2 (Fig. 1) are made by pressing in the magnetic field of an intermetallic compound powder, Tm, respectively, in the form of tablets with a height of 4 mm and a diameter of 4 mm. The magnets are soldered to the plate-conductor 3 of the same poles to each other. At room temperature, the contact is open due to the repulsion of the poles of the same magnet. The compensation temperature of the compound is. When the temperature reaches (lower than

compensation) in a nitrogen atmosphere in magnet 2, the direction of magnetization is reversed, i.e. the polarity of the poles is reversed, and as a result of the attraction of like poles, the magnets are attracted to each other and the contact is closed. If the ambient temperature starts to rise and exceeds the compensation temperature, then the magnetization again changes the direction to the opposite (takes the original direction), the polarity of the poles of the magnet 2 changes again, i.e. the magnets 1 and 2 are directed towards each other with like poles and the contact is opened due to pushing away like poles. .

The coercive force of the inversion magnet 2 in the range of meMn, epayyp 4.2-300 K is not less than 3.5 kOe. The intrinsic -magnetizing. Field of the inversion magnet 2 in this temperature range does not exceed 3.2 kOe, i.e. the condition. Not. Q1E + But is satisfied.

Claims (2)

1. Authors certificate of the USSR 517954, cl. H 01 H 37/58, 1973. 2. Authors certificate of the USSR 694847, cl. G 05 D 23/20, 1977. f- iJJU Nm