SU801133A1 - Maximum current distributor - Google Patents

Description

The invention relates to low-voltage apparatus, in particular to circuit breakers.

Known is the maximum release from the current of circuit breakers, which is an electromagnet containing a portion of the magnetic circuit made of thermomagnetic material. The known release is an electromagnet with a C-shaped yoke and lateral movement of the armature. An insert made of thermomagnetic material is installed in the yoke gap opposite the armature [1].

The drawbacks of the release are 15 relatively large amount of power consumption and increased material consumption, due to the need to magnetize two parallel magnetic circuits and the presence of a separate heater for the thermomagnetic insert.

Closest to the proposed 25 is the overcurrent release of the circuit breaker containing a valve electromagnet with a magnetic circuit section of thermo-magnetic material and a jq control winding located on one of the magnetic circuit rods [2].

However, the known release also consumes significant power and does not provide the opportunity to reduce material consumption.

The purpose of the invention is to reduce power consumption and reduce material consumption.

This goal is achieved by the fact that the thermomagnetic section is parallel to the core of the magnetic circuit on which the control winding is located, and the specified thermomagnetic section is located inside the control winding.

The drawing shows the overcurrent release.

The control winding 1 covers the core 2 and part 3 of the thermomagnetic section. The second part 4 of the thermomagnetic section goes around the gap 5 and ends above the armature 6. The spring 7 holds the armature b.

The overcurrent release operates as follows.

With unacceptable overload currents, the control winding 1 heats the timing parts 4, their magnetization 3 decreases and the magnetic flux in the gap 5 increases to a value sufficient to attract the armature 6 to the core 2. The larger the overload current, the faster the thermomagnetic section heats up and the earlier it attracts anchor, acting on the mechanism of free trip, opening the contacts of the switch. With a short circuit current, the thermomagnetic section saturates earlier than the main magnetic circuit, the magnetic leakage in the gap increases sharply, and the armature is attracted without delay.

The drawing shows indirect heating of the thermomagnetic section. Direct or combined heating is also possible.

The trip unit can be used in circuit breakers of various designs, which protect against overload currents with a time delay depending on the magnitude of the overload current and short-circuit currents without a time delay. Its use excludes the use of thermobimetal, which leads to the saving of such scarce materials as brass and silver-containing solders.

Claims (2)

The invention relates to low-voltage instrumentation, in particular, to automatic switches. The driver of the maximum current of the automatic switches is known: Gsta-vil is an electromagnet containing a section of a magnetic circuit made of a thermomagnetic material. The known trip unit is an electromagnet with a C-ring and transversely moving the core. An insert made of a thermomagnetic material is installed in the opposite side of the core gap. The disadvantages of the release are relatively large power consumption and increased consumption of materials due to the need to magnetize two parallel magnetic circuits and to have a separate thermomagnetic insert. Closest to the present invention is the overcurrent release of the circuit breaker containing a valve electromagnet with a magnetic circuit of thermal, magnetic material and a control winding placed on one of the cores of the magnetic circuit 2. However, the known release also consumes significant power and does not allow to reduce the consumption of materials . The purpose of the invention is to reduce power consumption and reduce material consumption. This goal is achieved by the fact that the thermomagnetic section is located parallel to the core of the magnetic circuit on which the control winding is located, and the specified thermomagnetic section is located inside the control winding. The drawing shows the overcurrent release. The control winding 1 encloses the core 2 and the part 3 of the thermomagnetic region. The second part 4 of the thermomagnetic region bends around the gap 5 and ends above the crust 6. The spring 7 holds the measles 6. The overcurrent release works as follows. If the overload currents are unacceptable, the control winding 1 heats the gr. Shomy magnetic parts 4, their magnetization decreases, and the magnetic flux in the gap 5 increases the magnitude sufficient to attract the core b to the core 2. The greater the magnitude of the load current, the faster the thermomagnetic section and the sooner the measles is attracted, I will act on the mechanism of free clamping of the breaker contacts. With a short-circuit current, the thermomagnetic section is saturated before the main magnetic circuit, the magnetic Ptbc in the gap increases sharply, and the bark is attracted without overtime. The drawing shows indirect heating of the thermomagnetic section. It is also possible direct or combined its heating. The release can be used in circuit breakers of various designs that protect against overload currents with a time delay depending on the magnitude of the overload current and short circuit currents without time delay. Its use eliminates the use of a thermobimetal, which leads to savings of such scarce materials as brass and silver-based solders. Claims The over-current release of the circuit breaker containing a valve-type electromagnet with a magnetic circuit section of a thermomagnetic material and a control winding placed on one of the magnetic core bars, is characterized in that, in order to reduce power consumption and reduce material intensity, the thermomagnetic portion is located parallel to the rod of the magnet duct on which the control winding is located. Moreover, the indicated thermomagnetic region is located inside the control winding. Sources of information taken into account during the examination 1. USSR author's certificate No. 524247, cl. N. 01 B 73/48, 1975. 2. USSR author's certificate number 517957, CL. H 01 H 71/40, 1973.