RU203984U1 - SYNPHASE INTERFERENCE THROTTLE - Google Patents

Abstract

The technical solution relates to the field of electrical engineering and can be used as common-mode interference suppression chokes made on toroidal magnetic circuits made of thin nanocrystalline iron-based and amorphous cobalt-based tapes intended for installation in interference suppression filters. cylindrically container and poured with a hardening compound containing ferromagnetic powders. Common-mode EMC chokes are divided into two-winding, three-winding and four-winding, with winding leads on two sides, for example, for installation in cylindrical structures with a vertical arrangement of common mode suppression chokes, with winding leads on one side, for example, for installation on a printed circuit board. can be used in versions with different values of rated load currents 10, 16, 25, 40, 63, 100, 200 A and, accordingly, the required cross-section of the magnetic circuit.

Description

The technical solution relates to the field of electrical engineering and can be used as a device for suppressing electromagnetic interference in the form of in-phase interference suppression chokes made on toroidal magnetic circuits made of thin nanocrystalline iron-based and amorphous cobalt-based tapes intended for installation in interference suppression filters.

Electronic devices are more and more around us in everyday life, and the issues of electromagnetic compatibility (EMC) are becoming more and more acute. In this regard, the requirements for common-mode filters are also becoming more stringent, which are used to protect devices from the penetration of high-frequency interference from the power supply network and to protect against the penetration of high-frequency interference into the network from switching power supplies and other devices using the switching mode.

The common mode filter application area covers a wide range of devices: telecommunications systems, switching power supplies, frequency converters, uninterruptible power supplies (UPS) and other products. With a typical magnetic permeability of 120,000 or more, common mode filter chokes based on magnetic cores made of thin nanocrystalline and amorphous ribbons require fewer winding turns, which provides low parasitic capacitance. They are smaller and provide higher insertion loss over a wide frequency range than traditional ferrite and permalloy products.

An effective way of suppressing electromagnetic interference in power supply lines and grounding of electricity consumers is the use of electromagnetic interference suppression devices in the form of common-mode interference suppression chokes installed in interference suppression filters. Filtration as a means of reducing the vulnerability of telecommunication equipment with interference suppression filters is devoted to many publications (for example, Kechiev L.N., Stepanov P.A. "EMC and information security in telecommunication systems" M .: Publishing House "Technologies", 2005).

Improving technical characteristics, increasing the inductance coefficient, reducing the mass and reducing the overall dimensions of common-mode interference suppression chokes is one of the main tasks, especially in aviation technology, in the development of aircraft, in rocketry and other fields of science and technology.

Known common-mode interference suppression chokes made on toroidal magnetic circuits, mainly on ferrite cores of the firms "EPCOS", "TE Connectivity", "WURTH ELEKTRONIK", and others.

Known magnetic cores from amorphous and nanocrystalline alloys of the Russian company NPP GAMMAMET LLC (http://www.gammamet.ru).

Known in-phase noise suppression chokes on magnetic circuits made of amorphous and nanocrystalline alloys of the Russian enterprise PJSC "MSTATOR" (www.mstator.ru).

All of these devices have a relatively small value of the inductance factor of the windings of the common-mode noise suppression chokes.

The task of the technical solution is to increase the inductance factor of the common-mode noise suppression chokes.

The problem is solved due to the fact that in-phase noise suppression chokes are made on toroidal magnetic circuits made of amorphous iron-based and nanocrystalline cobalt-based alloys in the form of thin strips, the twisted tape magnetic circuit is placed in a rigid protected container, the container has rounded edges, over which windings are wound , with an insulated copper wire, a container with windings is placed in a plastic cylindrical container and poured with a hardening compound containing ferromagnetic powders, while in-phase interference suppression chokes are divided into two-winding, three-winding and four-winding, with winding leads on two sides, for example, for installation in cylindrical structures with vertical arrangement of common-mode interference suppression chokes, with winding leads to one side, for example, for installation on a printed circuit board.

Common-mode interference suppression chokes can be used in versions with different values of rated load currents 10, 16, 25, 40, 63, 100, 200 A and, accordingly, the required value of the cross-section of the magnetic circuit.

The essence of the technical solution is illustrated by drawings, which show:

FIG. 1 - Common-mode four-winding interference suppression choke with winding leads to one side.

FIG. 2 - Common-mode four-winding interference suppression choke with winding leads on two sides, where it is indicated:

1. Winding 1.

2. Winding 2.

3. Winding 3.

4. Winding 4.

5. Toroidal magnetic circuit.

6. Plastic cylindrical container

"Filling" - Filling with a hardening compound.

H1, H2, H3, H4 - Conclusions of the beginning of windings 1, 2, 3, 4.

K1, K2, K3, K4 - Conclusions end of windings 1, 2, 3, 4.

The technical result, provided by the given set of features, is to increase the inductance coefficient of common-mode noise suppressing chokes.

Practical testing of the claimed technical solution confirmed an increase in the inductance factor by an average of 1.5 times of the windings of common-mode noise suppressing chokes on the same magnetic circuits, in equal measurement conditions with the difference between not filled and filled with compound. In comparison with other similar common-mode noise suppressing chokes, the value of the inductance factor of the windings is on average increased by 2 ... 2.5 times.

The presence of a causal relationship between the set of essential features of the claimed object and the achieved technical result is shown in Table 1.

The technical feasibility of the utility model follows from the description of common-mode noise suppressing chokes in statics and dynamics with the practical achievement of the specified technical result.

Claims (5)

1. A common-mode interference suppression choke made on a toroidal magnetic circuit, made of thin amorphous iron-based strips, a twisted strip magnetic circuit is placed in a rigid protected container, the container has rounded edges, over which windings are wound with insulated copper wires, characterized in that the container with windings, placed in a plastic cylindrical container, filled with a hardening compound containing ferromagnetic powders. 2. The common-mode noise suppression choke according to claim 1, differs in that it is made on a toroidal magnetic circuit of a nanocrystalline, cobalt-based alloy, in the form of thin strips. 3. The common-mode interference suppression choke according to claim 1, differs in that chokes are divided into two-winding, three-winding and four-winding. 4. The common-mode interference suppression choke according to claim 1, differs in that the leads of the choke windings are made both on two sides and on one side. 5. The common-mode interference suppression choke according to claim 1, differs in that the chokes are made with different values of rated load currents of 10, 16, 25, 40, 63, 100, 200 A and, accordingly, the required cross-section of the magnetic circuit.

Images