RU2094887C1 - Circuit breaker electromagnetic release - Google Patents

Abstract

FIELD: electrical engineering; circuit-opening devices, including air circuit breakers designed for overload and short-circuit protection of loads. SUBSTANCE: electromagnetic release has magnetic system built up of core 1 of magnetic circuit 2, sleeve 3 with winding 4, nonmagnetic forward-stroke armature 5, and magnetic liquid 6 mounted on core 1. Sleeve 3, winding 4, and nonmagnetic armature 5 are arranged coaxially. Nonmagnetic armature 5 is held down by spring 7 on magnetic circuit 2 and forms gap 8 with core 1 and space 9 in gap between armature 5 and sleeve 3. Magnetic liquid 6 is contained in gap 8 between core 1 and nonmagnetic armature 5 in space 9. Magnetic liquid 6 is held around nonmagnetic armature 5 whose tail end is free to engage trigger latch of circuit breaker 11 during its operation. EFFECT: improved reliability of release. 4 dwg

Description

 The invention relates to electrical engineering, in particular to the field of electrical engineering and can be used in air circuit breakers designed to protect consumers of electrical energy from current overloads and short circuits.

 Known electromagnetic releases serving as trip devices of contact devices, for example, maximum current releases in circuit breakers with high breaking capacity of the S 500 series (Air Force catalog "Circuit Breakers of the S 500 Series", 1989).

 The aforementioned electromagnetic trip units are also widely used in domestic series of circuit breakers designed to protect electric circuits and electric motors (circuit breakers series VA 14, Electrical Engineering of the USSR, Informelectro, 1988).

 The design of the known maximum current releases contains a core, a magnetic circuit, a linear spring anchor with two shanks, a coil made by a winding wire. The forward anchor forms with the core a working gap in the sleeve and a cavity in the gap between it and the sleeve to allow passage of the environment, for example air, when moving to actuation and returning the armature to its original state.

 The principle of operation of the known design of maximum current releases is to create in the magnetic circuit an overload or short circuit current of a magnetomotive force, which allows the magnetic flux to pass through the working gap of the magnetic circuit, sufficient to attract the armature to the core. In this case, the moving anchor, choosing the working gap, interacts with one shank with the movable contact holder of the switch, and with the other with the latch of the free trip mechanism.

 The magnetic field and magnetic flux in the magnetic circuit of the known maximum current release are unevenly distributed over the cross section and length of the core. The uneven density of the lines of force is due to the small length of the core in comparison with the size of its diameter and the peculiarity of the shape of the magnetic circuit.

 The design flaws of the known electromagnetic maximum current releases include: design complexity, the inability to act on the latch of the free trip mechanism until the main contacts of the circuit breaker are discarded, large energy losses in the working air gap of the magnetic circuit, and the non-uniformity of the magnetic flux in the working gap to improve the response characteristics.

 The construction of electromagnetic overcurrent releases was somewhat simplified in the circuit breakers of the VA 19 series, manufactured according to the technical specifications of TU 16 89, IGR. 641233.007 TU, with the exception of one shank at the anchor. This known design of the electromagnetic maximum current release is the closest in technical essence to the proposed solution and adopted by the authors for a prototype that contains a core, a magnetic circuit and coaxially mounted sleeve with a winding and linear spring-loaded armature with a shank. The anchor forms a working gap with a core and a gap with a sleeve. In the gaps of the armature with the core and the sleeve, a cavity is formed for passing the environment during its movement and the possibility of interaction with the shank and the latch of the switch when triggered.

The disadvantages of the known overcurrent release selected for the prototype include:
1. Large losses of magnetomotive force to conduct magnetic flux through the air gap of the magnetic circuit.

 2. The design does not use the inherent unevenness of the magnetic field while ensuring the movement of the armature to operate.

 3. High metal consumption due to steel consumption. The impossibility of reducing the metal structure without deteriorating the response characteristics.

 4. The force of impact of the anchor on the latch when triggered is unnecessarily large, which reduces the resource and reliability of the device. Excessive impact energy is associated with the dependence of the magnetic flux growth not only on the current, but also on the position of the armature when it moves to the core.

 The purpose of the invention is to eliminate these drawbacks, namely, to improve the design of the electromagnetic release, increase the conductivity of the magnetic circuit, obtain and use additional heterogeneity of the magnetic field for the movement of the armature. This goal is achieved by the fact that in an electromagnetic release for a circuit breaker containing a magnetic system consisting of a core, a magnetic circuit and coaxially mounted winding with a sleeve and linear spring-loaded armature, in the gaps of which a core is formed with a core and sleeve for the passage of the environment and the possibility of interaction with the shank with the latch of the switch when triggered, the magnetic system is made in the form of a closed magnetic circuit containing a magnetic circuit, core and magnet liquid, and the anchor is made of non-magnetic material, while the magnetic fluid is placed in the cavity of the sleeve so that it occupies a working gap between the core and the armature and covers the armature.

 The specificity of magnetic fluids is associated with the presence in them of a non-uniform magnetic field of a bulk mechanical force F acting on an immersed non-magnetic body and proportional to the magnetization of the magnetic fluid. A non-magnetic body immersed in a magnetic fluid will “pop up” with a certain magnetization of the fluid and “sink” with its fall (Magnetic fluids / B.M. Berkovsky, V.F. Medvedev, M.S. Krakov M. Chemistry, 1989. 240 s).

 Therefore, the essence of the proposed technical solution is to use magnetic fluid to conduct magnetic flux in the magnetic circuit of the electromagnetic release and to provide “pushing” (actuation) of the armature with sufficient magnetization of the magnetic fluid that occurs when the load current reaches a value equal to the set value for the operation current.

 This is achieved by the fact that in an electromagnetic release for a circuit breaker containing a core, a magnetic core and coaxially mounted sleeve with a winding and a linear spring-loaded armature with a shank, in the gaps of which a core is formed with a core and sleeve for the passage of the medium surrounding the armature, in accordance with the invention, the armature made of non-magnetic material, and the electromagnetic release itself is equipped with a magnetic fluid. In this case, the magnetic fluid is placed in the cavity of the sleeve so that it occupies the gap between the core and the armature, the cavity in the gap between the armature and the armature and covers the anchor.

 In FIG. 1 shows the proposed electromagnetic release for a circuit breaker in the context in the initial position without current in the winding circuit; in FIG. 2 he, with a load current in the winding circuit does not provide a magnetic flux that can cause the armature to trip. The direction of the current is indicated in the cross section of the windings and the arrow in the lead wire; in FIG. 3 the proposed electromagnetic release for the circuit breaker in the context in the "actuation" position. The shank of the moving armature resets the trigger release latch. Thin lines with arrows indicate the lines of force of the magnetic field. In FIG. 4 proposed electromagnetic release for a circuit breaker operating in a circuit breaker VA-19.

 The proposed electromagnetic release for the circuit breaker contains a magnetic system consisting of a core 1, a magnetic circuit 2, a sleeve 3 with a winding 4, a non-magnetic armature 5 and a magnetic fluid 6 located on the core 1, a winding 4.

 The sleeve 3, the winding 4 and the non-magnetic armature 5 are installed coaxially. Non-magnetic armature 5 is spring-loaded 7 to the magnetic circuit 2 and forms a gap 8 with core 1 and a cavity 9 in the gap with sleeve 3. In the gap 8 between the core 1 and non-magnetic armature 5 in the cavity 9 there is a magnetic fluid 6. Non-magnetic armature 5 is surrounded by magnetic fluid 6 , and its shank 10 has the ability to interact with the trigger latch of the switch 11 when triggered (Fig. 1, 4).

The proposed electromagnetic maximum current release operates as follows:
At rated current load and processing load coil circuit I _nom ≅I _LOAD ≅I _t
In the initial position, in the absence of current in the turns of winding 4, the armature 5 of the electromagnetic release covered by magnetic fluid 6 is affected by the forces: the weight of the armature 5 -P _I , the compression of the spring 7 F _pr directed towards the core 1, and the Archimedes force f, opposing them. The strength of Archimedes f is smaller in magnitude than the sum of the preload forces and the weight of the anchor f <P _i + F, _etc. Therefore, the anchor 5 is at rest at a distance of the gap 8 from the core 1 (Fig. 1).

 When the rated current or the process load current passes through the main circuit of the circuit breaker and through the turns of the winding 4, the magnetomotive force develops in the core 1 a magnetic flux uneven along its length, passing through the magnetic fluid 6, covering the non-magnetic armature 5 to the magnetic circuit 2. The highest line density magnetic field to the surface of the core 1 in the gap with a non-magnetic armature 5 (under the armature), the smallest over the non-magnetic armature 5 at the surface of the magnetic circuit 2 (in Fig. 2 the density of the magnetic field lines th field is not shown conditionally).

 The effective density of the magnetic fluid 6 in a non-uniform magnetic field increases in proportion to the magnetization, the density of the lines of force of the magnetic field. Therefore, the volumetric mechanical force F, caused by the density difference of the non-magnetic armature 5 and the magnetic fluid 6, acting on the non-magnetic armature 5, tends to lift it from the core 1 and push it out of the magnetic fluid 6.

However, the magnitude of the force F pushing the non-magnetic armature 5 at the indicated currents in the main circuit of the circuit breaker is still insufficient to overcome the total force of the spring 7, pressing the shank 10 and the weight of the non-magnetic armature 5, F <F _CR + P _i .

 All moving elements of the electromagnetic release are in the initial state (Fig. 2).

II. With the occurrence of short-circuit currents equal to or greater than the set value for the operating current I _kz ≥I _cf
The increasing short circuit current passing through the turns of the winding 4 causes a magnetomotive force in the core 1, which ensures that the magnetic circuit increases and increases in magnitude of the magnetic flux, increasing the magnetization of the magnetic fluid 6.

 Since the electromagnetic release is equipped with a magnetic fluid 6 having a higher magnetic permeability than air (for example, μ 15) and it is placed in the cavity 9 of the sleeve 3 and between the core 1 and the magnetic core 2, the loss of magnetomotive force on the magnetic flux is reduced compared to prototype costs.

 The density of the lines of force under the anchor does not depend on its position and always exceeds the density of the lines of force above the anchor.

 The non-uniformity of the magnetic field in the magnetic circuit inherent in electromagnetic tripods with cores extending slightly larger than their diameter is increased by the fact that the forward link armature 5 located on the magnetic flux path is made of non-magnetic material, for example, GOST 9359-80 MFV1 amine plastic, with low magnetic permeability and covered by magnetic fluid 6.

In a non-uniform magnetic field with a short circuit current exceeding the setpoint for the operating current, the effective density of the magnetic fluid 6, covering the non-magnetic armature 5, is much higher than the density of the non-magnetic armature, which provides an instant increase in the force pushing the armature 5 (F> F _CR + P _I ) Anchor 5 instantly pops up, leaves the core 1 and shank 10 breaks the trigger latch 11 of the switch.

 The magnitude of the magnetic flux does not depend on the position of the non-magnetic armature 5 when operating for actuation, therefore, the impact energy of the shank 10 on the trigger latch 11 is limited in comparison with the prototype, which increases the service life and reliability of the apparatus.

With the circuit breaker after a failure of the trigger latch the fault current with the magnetic flux density decreases effective magnetic fluid 6 and the buoyant force F. Under the influence of the spring force and 7 weight P _i nonmagnetic armature 5 returns to its original condition and is covered by the magnetic fluid 6.

 In the case of a slow monotonous increase in the load current and approaching the value of the setpoint for the operating current, the ejection force F can exceed the resistance of the spring 7 until the current reaches the setpoint. Anchor 5 extends the shank 10 to the latch 11, but does not provide a trigger. The latch is reset and the circuit breaker trips only when the load current reaches the set current setting.

 The materiality of each of the distinguishing features of the proposed technical solution as follows determines the achievement of the claimed positive effect.

The proposed electromagnetic release for the circuit breaker is more perfect than the prototype, as it uses additional heterogeneity of the magnetic field for the movement of the armature and has advantages in comparison with the prototype:
smaller losses of the magnetomotive force for conducting the magnetic flux (in the gap is a magnetic fluid, not air);
less metal construction (the anchor is made of plastic, not steel);
smaller, rational in magnitude (saving resource and reliability) impact energy during instantaneous operation, provided by a magnetic flux independent of the position of the moving armature.

 A prototype of the proposed electromagnetic release for the circuit breaker, built into the circuit breaker VA 19, which during the bench test, provided its operation with short-circuit currents, was made.

Claims (1)

 An electromagnetic release for a circuit breaker, comprising a magnetic system consisting of a core, a magnetic circuit and coaxially mounted winding with a sleeve and a linear spring-loaded armature, a cavity is formed in the gaps between the armature, core and sleeve to pass the environment, the armature shaft is arranged to interact with the switch latch upon operation, characterized in that the anchor is made of non-magnetic material, a magnetic fluid is placed in the cavity of the sleeve so that it animaet working air gap between the core and the armature and the armature covers to form a closed magnetic circuit consisting of a yoke and a magnetic core liquid.

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