SU698068A1 - Maximum current disconnector - Google Patents

Description

The invention relates to the field of electrical equipment, in particular, to the overcurrent release of circuit breakers. The overcurrent breakers of circuit breakers are known, containing measles and two magnetic cores: the main L-shaped form and made of electrical steel, with a magnetizing winding and an additional one of the thermomagnetic material heated by the current of the protected circuit 1. Such a release is relatively large. The prototype of the invention is the overcurrent release of the circuit breaker, the main U-shaped magnetic core with a magnetizing winding placed on one of its cores, measles, the axis of rotation of which passes through the end of another core, and an additional U-shaped magnetic circuit heated by current protected circuit. One end of the additional magnetic core is fixedly mounted at the base of the core, on which the magnetizing winding is placed, and the other end is placed above the end of the ramp, which acts on the Ntexa free trip low {2. The disadvantages of this release are relatively large size and significant consumption of materials. The purpose of the invention is to reduce the dimensions and reduce the material consumption of the release. For this, the two end sections of the additional magnetic circuit are made of electrical steel, and the middle section is made of a thermomagnetic material. The drawing shows the release. It has a U-shaped main magnetic core 1, a magnetizing winding 2 located on core 3, measles 4 and an additional U-shaped magnetic core 5 with an additional winding 6. The additional magnetic core has two end sections 7 and 8 of electrical steel and a middle section 9 from thermomagnetic material. Section 9 is heated by the current of the protected circuit, either directly or indirectly. The magnetizing and additional windings are interconnected in series. The anchor is held by the opposing spring (not shown).

The device works as follows.

When current flows through the protected circuit ON to the series connection of the magnetizing winding 2 and the additional winding 6 in the core 3 and the U-shaped additional magnetic conductor 5, magnetic fluxes F and F appear, respectively. Magnetic flux

F at the base of the core is branched: part F goes along the ferromagnetic magnetic conductor 1, and part Fd goes along the additional magnetic conductor. The smaller the magnetic resistance of the additional magnetic circuit, the greater the magnitude of the magnetic flux. branches into it.

Since the magnetic permeability of electrical steels is significantly higher than the magnetic permeability of thermomagnetic materials, when making the end sections 7 and 8 of electrical steel instead of the thermomagnetic material with the same magnetic resistance of the additional magnetic circuit, the cross section of the end sections is significantly reduced. This leads to a decrease in the dimensions of the release and a decrease in its material intensity.

The magnetic flux F is directed so that it enhances the flux F, in the additional magnetic core (F2, + FD). The magnetic fluxes F and F. create magnetic forces acting on the measles 4 in two opposite directions: one force tends to pull the measles to the core 3, and the other to the end 7 of the additional magnetic core. With the passage of the rated current in the protected circuit, the force acting from the side of the core to measles is insufficient for its attraction. In addition, with the passage of the rated current, the additional magnetic core is heated slightly.

With the passage of a small emergency current, the force acting from the core to the measles is still insufficient to attract it, but section 9 of the thermomagnetic material heats up and loses its magnetic properties with time. As part 9 is heated, the force acting on measles from the side of the additional magnetic core 5 decreases, and the force from the side of the core is taken into account. After a certain time (time delay before shutdown), the force acting on measles on the side of the core is sufficient to attract the core to the core. When moving, measles affects the mechanism of free tripping, which places the circuit breaker in the open position. The greater the small emergency current, the faster the additional magnetic core 5 heats up and

the faster the switch is turned off, i.e. less time delay before shutting down.

When a high emergency current (instantaneous operation current 2) occurs in the protected circuit, the additional magnetic core is saturated, since the saturation induction of the thermomagnetic materials is approximately two times less than the electrical current x

g of steels, and all the excess magnetic flux rushes into the main magnetic core. As a result, the force of attraction of the core 4 from the core 3 with a constant force of attraction of the core to the additional magnetic conductor sharply increases, therefore the measles, overcoming the resistance of the opposing spring, is attracted to the core without time lag. When moving, it acts on the mechanism of free tripping, which places the circuit breaker in the open position.

The described maximum current release, which combines the protection of the circuit against small alarm currents with time delay and against large alarm currents without time delay, is intended for use in 0 general industrial switches. Such a release has smaller dimensions and weight, i.e. It has a lower material consumption compared with the analogous release. Since ce5 on electrical steel is lower than the price of thermomagnetic materials, such a release has a lower cost.

Claims (2)

1. USSR author's certificate No. 581525, cl. H 01 rf 73/48, 1977. 2. USSR author's certificate in application number 2525426/07, cl. H 01 H 73/48, according to which the decision to issue a copyright certificate was made. "T H