SU738011A1 - Maximum current breaker - Google Patents

Description

The invention relates to the field of electrical equipment, in particular, to automatic switches. Known disconnectors with maximum current to protect the network from load currents and short-circuit currents are known, which contain an W-shaped magnetic conductor, one of whose rods is made of a thermomagnetic material, Curie point and saturation induction G of which is lower than the Curie point and the saturation induction of the remaining parts of the magnetic conductor, the winding located on the center of the rod, and the rotating measles installed on the middle rod with gaps relate Other rods, with a core of thermomagnetic material located on the side opposite to the working gap .1. The disadvantage of this release is the lack of a smooth adjustment of the setting of the overload current, i.e. the absence of a smooth adjustment of the degree of heating by the j-current of the protected network of a thermomagnetic rod. The prototype of the proposed device is the overcurrent release of the automatic switch that contains the main magnetic circuit of the U-shaped form with the magnetizing winding placed on one of its cores, the measles, the axis of rotation of which passes through the end of the other core, the toxins, additional magnetic U-shaped a ferromagnetic material heated by the current of the protected circuit, one horse of which is fixedly mounted at the base of the core on which the magnetizing winding is placed And the other end of the further magnetic circuit is placed over the end of the armature, acting on the free disengagement mechanism 2. However, this device does not allow to smoothly adjust the overload current setting, which complicates the manufacturing technology. The aim of the invention is to simplify the manufacturing technology by ensuring the smooth adjustment of the overload current setting. To achieve this goal, the device is equipped with a metal part of a nonmagnetic material with high electrical resistivity.

rigidly fastened on an additional P-shaped magnetic core made of a thermomagnetic material, one of the conclusions of the magnetizing winding is electrically connected to what was said; an additional magnetic circuit is electrically connected to a metal part of a nonmagnetic material with high electrical resistivity in such a way that Direct heating of the specified additional magnetic circuit. In addition, in the considered release, the maximum tOKa current lead to the metal part from a non-magnetic material with a high electrical resistivity can be made with the possibility of moving the current lead along the specified metal part. In the specified overcurrent release, the metal part of a nonmagnetic material with high electrical resistivity can be made in the form of a pin.

The proposal is illustrated in a drawing.

The electromagnetic system contains a U-shaped magnetic circuit 1, a magnetizing winding 2 located on the core 3, measles 4. The additional magnetic circuit 5 of the U-shaped form is made of a thermomagnetic material and is heated by the current of the protected network. The drawing shows direct heating. Indirect and combined heating of the magnetic circuit 5 is also possible. On the additional magnetic core 5, a pin 6 of a nonmagnetic material with high electrical resistivity is rigidly mounted. One current lead 7 is welded at a certain place to an additional magnetic conductor 5, and the second current lead 8 is attached to the spike e between two nuts 9 and 10 with the possibility of its movement along the length of the stud. Anchor 4 is held by an opposing spring (not shown). The arrows indicate the direction of the magnetic flux.

The device works as follows.

When the current of the protected network flows through the magnetizing winding 2 in, the core 13 produces a magnetic flux F, which branches at the base of the core in inverse proportion to the magnetic resistances of the branches; magnetic circuit 1, measles 4 and additional magnetic core 5, magnetic flux F in the branch of magnetic circuit 1, measles 4 creates an electromagnetic force that tends to pull measles 4 to the core 3. Magnetic flux F- in the additional magnetic core creates an electromagnetic force that presses the measles 4 to the additional magnetic circuit 5. When an emergency current occurs in a protected network to a certain value, the electromagnetic force acting on measles from the core side is less than the sum of the forces of the opposing spring; electromagnetic force from the side of the additional magnetic circuit. Since the induction of saturation of known thermomagnetic materials is about 2-3 times lower than the saturation induction of electrical steels, then at a certain value of the emergency current the magnetic flux Fz in the additional magnetic core stops growing (it is saturated). Starting from this value of the emergency current, the magnetic flux F / a continues to grow with it and the electromagnetic force from the core 3.

When the emergency current reaches the short-circuit current setting, the electromagnetic force acting on the measles on the side of the core 3 is greater than the sum of the opposing spring force and the electromagnetic force on the side of the additional magnetic circuit 5. The armature is attracted to the core 3 and during its movement it acts on the free tripping mechanism, which and puts the circuit breaker to the open position. When the overload current passes through the protected network, the additional magnetic core 5 heats up and loses its magnetic properties over time, i.e. over time, its resistance increases. This causes an increase in the magnetic flux Φ by decreasing the magnetic flux Φ2. And this, in turn, leads to a decrease in the electromagnetic force of the attraction of the cortex 4 to the additional magnetic conductor and to an increase in the electromagnetic force of the attraction of the cortex 4 to the core 3. After some time (time delay before shutdown), the measles 4 are attracted to the core 3 and - as it moves through the free-release mechanism, the circuit-breaker moves to the open position. The overload current setting can be adjusted stepwise by a fixed current lead to different parts of the additional magnetic circuit. This results in a step change in resistance, i.e. the degree of heating of the additional magnetic circuit varies in steps.

A gradual change in the degree of heating of an additional magnetic circuit, i.e. current overload 1si, carried out by threaded movement on the pin of the movable current lead.

Thus, the proposed automatic current overrun

Claims (2)

Claim 1. Application I 2475778/07, cl. N 01 N 83/00, 1977, according to which 35 a decision was made to issue a copyright certificate .. 1. The overcurrent release of the circuit breaker, containing the main U-shaped magnetic core with a magnetizing winding, placed on one of its cores, an armature, the axis of rotation of which passes through the end face of the other core, additional current leads. U-shaped magnetic core made of thermomagnetic material heated by the current of the protected circuit, one end of which is fixedly fixed at the base of the core on which the magnetizing winding is placed, and the other end of the additional magnetic core is placed above the end of the armature acting on the free tripping mechanism, characterized in that , in order to simplify the manufacturing technology by providing a smooth adjustment of the overload current setting, the device is equipped with a metal part of non-magnetic material with a high hard electrical resistivity - on an additional magnetic circuit of a U-shaped fork made of thermomagnetic material, one of the terminals of the magnetizing winding is electrically connected to the indicated additional magnetic circuit, and one of the current leads is electrically connected to a metal part of a non-magnetic material with high electrical resistivity in such a way that direct heating * 15 specified additional magnetic circuit .. 2. Release on π. 1, with the fact that the current supply to the metal part of non-magnetic material with high electrical resistivity is made with the possibility of moving the current, supply along the specified metal part. 25 3. Release according to π. 1, the fact that the metal part of a non-magnetic material with high electrical resistivity is made in the form of a __ stud. '' Sources of information taken into account in the examination 2. Application No. 2525426/07, cl. N 01 N 73/48, 1977, according to which a decision was made to issue the copyright ^x 40 certificate. ЦНИИПИ Order 26.71 / 31 Circulation 844 Subscription PPP ’’ Patent Branch, Uzhhorod, st. Project, 4