RU2276421C1 - Two-position electromagnet - Google Patents

Abstract

FIELD: electrical engineering; operating mechanisms of switches including high-voltage vacuum switches.

SUBSTANCE: fixed part of two-position electromagnet has coaxially disposed parts (cylindrical core with circular projection in central part and circular case). Fixed part components are joined together by means of nonmagnetic components placed in gap between circular projection of core and case; these components only partially fill the gap in azimuth. Coils are disposed on core between core and case on both ends of circular projection; permanent magnets are disposed beyond gap portion free from nonmagnetic components between circular projection of core and case; movable part has nonmagnetic rod disposed in core hole and two disk-shaped armatures secured on rod ends.

EFFECT: enhanced holding force of magnetic-circuit moving part when coils are de-energized.

1 cl, 2 dwg

Description

The invention relates to the field of electrical engineering, namely to electrical devices, and more specifically to electromagnets, and can be used for drives of electrical switches, in particular vacuum circuit breakers of high voltage.

A two-position electromagnet is known, consisting of a coil, a fixed part of a magnetic circuit made of soft magnetic ferromagnetic material in the form of two flanges (covers) - a persistent (upper) and a passage (lower), annular magnet made of magnetically hard ferromagnetic material, a movable part of the magnetic circuit (anchor) made of soft magnetic ferromagnetic material in the form of a cylinder and a return spring located between the armature and the stop flange [1].

In the initial position, due to the action of pressing the return spring, the anchor leaves the stop flange and a non-magnetic (air) gap is formed between them. If an electric current of a certain magnitude is passed through the coil, a magnetic flux will appear in the magnetic circuit, which will magnetize the armature and flanges, and the armature, moving in the hole of the passage flange, will be attracted to the stop flange, compressing the return spring. At the same time, an annular magnet made of magnetically hard ferromagnetic material is magnetized in the axial direction. If you turn off the current in the coil, the armature remains in an attracted position due to the action of the residual magnetic flux, which is created by a magnetized ring magnet. To return the anchor to its original position through the coil, it is necessary to pass a current in the opposite direction, due to which the ring magnet is demagnetized, the magnetic flux decreases and under the action of the spring the armature moves away from the stop flange.

Using the principle of magnetization reversal of a ring magnet makes it impossible to use modern highly coercive magnetically hard materials for their manufacture, for magnetization reversal of which very high currents must be passed through the coil, which requires powerful energy sources in the control circuits and creates switching problems for such currents. The use of hard magnetic materials with a relatively low coercive force reduces the magnetic flux in the working gap and, as a result, reduces the force that holds the armature in an drawn position, which is a significant drawback of this device.

The ALSTOM two-position electromagnet is also known, consisting of a coil, a fixed part of an armored magnetic circuit, an annular magnet made of hard magnetic ferromagnetic material, a moving part of the magnetic circuit (armature) in the form of a cylinder, and auxiliary elements of the fixed part of the magnetic circuit that prevent demagnetization of the permanent magnet when changing direction current in the coil due to the flow of the demagnetizing magnetic flux from the branch of the circuit in which the permanent magnet is located, into the shunting magnetic circuit [2].

The disadvantage of this design of the electromagnet is the relatively small holding force of the moving part of the magnetic circuit when the coil is de-energized in the on position, because the holding force in this position is created in only one gap and is limited by the magnitude of the magnetic induction of saturation of the magnetic circuit material, which in modern magnetically soft materials is approximately 2 T, and the value of the retention force corresponding to such an induction is 16 kg / cm ² .

Closest to the proposed technical solution is a two-position electromagnet (actuator), which is used in high-voltage vacuum circuit breakers VM1 of ABB concern [3].

The on-off electromagnet of the VM1 circuit breaker consists of a fixed part of the magnetic circuit, a moving part, two coils and permanent magnets. The moving part of the magnetic circuit - the anchor is a parallelepiped made of soft magnetic material. The coils are located in space parallel to each other at a distance that is approximately equal to the width of the cross section of the armature, and have rectangular openings with dimensions that approximately equal the width and depth of the cross section of the arm. The anchor is located inside the hole of the coil, and the length of the armature is less than the distance between the opposite surfaces of the coils perpendicular to the axis of the armature by the value of the armature stroke. The fixed part of the magnetic circuit is a package of rectangular ferromagnetic plates, the thickness of which is approximately equal to the depth of the transverse intersection of the armature. The plates have rectangular holes and two rectangular protrusions that are directed into the hole and are located opposite one another in the middle of the hole. The protrusions have a width that is approximately equal to the distance between the adjacent coil surfaces perpendicular to the axis of the armature. Inside the opening of the plate package, there are coils and an anchor that moves freely in the opening of the coils. On the surfaces of the protrusions there are highly coercive permanent magnets that are parallelepipeds, the width and depth of which are approximately equal to the width of the protrusion in the hole of the fixed part of the magnetic circuit and the thickness of the plate pack of the fixed part of the magnetic circuit. The thickness of the magnet is chosen so that it almost completely fills the gap between the end face of the protrusion of the fixed part of the magnetic circuit and the side surface of the armature. The moving part of the electromagnet also includes a non-magnetic cylinder-shaped rod, which is rigidly fastened to the anchor, with the vertical axis of the armature (in the direction of its length) and the axis of the rod coincide. On the axis of the fixed part of the magnetic circuit, which coincides with the axis of the armature, there are two bushings, in the holes of which the rod moves, which transmits the movement of the armature to the moving contacts of the vacuum chambers of the switch.

If the anchor is pressed against the fixed part of the magnetic circuit, it is reliably held in this position with de-energized coils due to the magnetic flux created by the permanent magnets. This magnetic flux significantly exceeds the flux through the opposite end surface of the armature, because there is a relatively large non-magnetic gap between it and the fixed part of the magnetic circuit, which is approximately equal to the armature travel. If a current of an appropriate magnitude and direction is passed through a coil located on the side of this gap, the armature will begin to move in such a way that the non-magnetic gap on the side of the coil through which current flows will begin to decrease, and the gap on the side of the de-energized coil will begin to increase. When the anchor abuts against the fixed part of the magnetic circuit, it will remain in this position even after disconnecting the corresponding coil due to the magnetic flux, which flows towards a smaller gap. This electromagnet is a two-position, because it has two stable positions with de-energized coils.

The disadvantage of this design of the electromagnet is the relatively small holding force of the moving part of the magnetic circuit with de-energized coils, because the holding force in each steady state is created in only one gap and is limited by the magnitude of the magnetic induction of saturation of the magnetic circuit material, which in modern magnetically soft materials is approximately 2 T, and the corresponding such an induction, the value of the retention force is 16 kg / cm ² .

The basis of the invention is the task of improving the two-position electromagnet, in which, due to a different design and other connections between its parts, an increase in the holding force of the moving part of the magnetic circuit with de-energized coils is provided, and due to this, the efficiency and reliability of operation of electric switches in which such electromagnets are used are increased.

The solution to this problem is achieved by the fact that in a two-position electromagnet consisting of a fixed part of the magnetic circuit, a moving part, two coils and permanent magnets, according to the invention, the fixed part of the magnetic circuit consists of coaxially arranged parts — a cylindrical core with a cylindrical hole and an annular protrusion in the middle part and an annular case, the plane of the ends of which are parallel to each other and perpendicular to the axis of the fixed part, the inner diameter of the annular body p the outer diameter of the annular protrusion on the core is reduced, the parts of the fixed part are interconnected by non-magnetic parts located in the gap between the annular protrusion of the core and the housing, and these parts in azimuth only partially fill the gap, the coils are located between the core and the housing on both sides of the annular protrusion on the core, permanent magnets are located outside the part of the gap between the annular protrusion of the core and the housing occupied by non-magnetic parts, and the movable part um from a non-magnetic rod located in the hole of the core, and the axial size of the rod part with a diameter equal to the diameter of the hole in the core exceeds the axial size of the fixed part of the magnetic circuit by the stroke of the moving part, and two disk-shaped anchors coaxial with the rod fixed to the ends of the rod part with a diameter that equals the diameter of the hole in the core.

As a result of using the claimed invention, a technical result is obtained consisting in increasing the holding force of the moving part of the magnetic circuit with de-energized coils.

The proposed design features of the inventive two-position electromagnet allow two gaps: between the armature and the core, and also between the armature and the body, in which a holding force is created in each steady state (i.e., the force that presses the armature against the fixed part of the magnetic circuit), due to what is achieved by increasing the total holding force of the moving part of the magnetic circuit with de-energized coils.

The invention is illustrated by drawings, where figure 1 schematically shows a profile projection (axial section) of the proposed two-position electromagnet, and figure 2 is its horizontal projection (central section).

On the presented drawings of the proposed two-position electromagnet indicated: 1 - core; 2 - an annular protrusion on the core; 3 - case; 4, 5 - coils; 6, 7 - disk-shaped anchors; 8 - non-magnetic stock; 9 - a permanent magnet; 10 - non-magnetic part connecting the core to the housing.

The device operates as follows. When one of the anchors, for example, 6 is pressed against the fixed part of the magnetic circuit, which consists of a core 1 with an annular protrusion 2 and an annular housing 3, the housing and the core being connected by non-magnetic parts 10 that only partially fill the gap between the core protrusion and the housing, the corresponding anchor is reliably held in this position with de-energized coils 4 and 5, due to the magnetic flux created by the permanent magnets 9, which are located outside the part of the gap occupied by non-magnetic parts ezhdu annular protrusion of the core and the housing. This magnetic flux significantly exceeds the flux through the opposite armature 7, because there is a relatively large non-magnetic gap between this armature and the fixed part of the magnetic circuit, which is approximately twice as long as the armature travel. If a current of the corresponding magnitude and direction is passed through the coil 5 located on the side of this gap, the magnetic flux created by the current of the coil 5 through the armature 6 pressed to the fixed part of the magnetic circuit will be subtracted from the flux created by the permanent magnets 9, therefore, the total magnetic flux through this anchor will decrease. The magnetic flux created by the current of the coil 5 through the opposite armature 7 will be added to the flux created by the permanent magnet. Therefore, the total magnetic flux through this armature, on the contrary, will increase and the armature 6 and 7 due to the rod 8 that connects them will begin to move in such a way that the non-magnetic gap from the side of the coil through which current flows begins to decrease, and the gap from the side of the de-energized coil starts to increase. When the armature 7 rests against the fixed part of the magnetic circuit, it will remain in this position even after disconnecting the corresponding coil due to the magnetic flux created by the permanent magnets, which flows towards a smaller gap. Switching the electromagnet to its original position is provided by passing a current of the corresponding magnitude and direction through coil 4. This electromagnet is on-off, because it has two stable positions with de-energized coils.

Due to the fact that the force that presses the anchor to the fixed part of the magnetic circuit in the proposed design of the electromagnet is created in two gaps - between the armature and the core, and also between the armature and the body, the total holding force of the moving part of the magnetic circuit with de-energized coils is approximately doubled compared to the force retention in a known electromagnet, where the retention force is created in only one gap, with the same magnitude of the magnetic flux, that is, with the same mass of permanent magnets, and with the same echnom magnetic circuit section.

The effectiveness of the proposed device is confirmed by comparative tests of the on-off electromagnet of the VM1 circuit breaker according to the prototype and the proposed on-off electromagnet, which, with smaller overall dimensions, a smaller total mass and a smaller mass of permanent magnets, provided a holding force of approximately 10 kN, while the electromagnetic circuit of the VM1 switch provided a holding force of approximately 4 kN

INFORMATION SOURCES

1. Vacuum circuit breakers BB / TEL series. Operation manual ITEA674152.003RE. 2002 year

2. AMD Magnetantrieb. AMD - Hochentwuckelte magnetische ANTRIEBE far Vakuum-Leistungsschalter / ALSTOM catalog.

3. VM1. Vakuum-Leistungsschalter mit Magnetantrieb / Catalog ABB Calor Emag Mittelspannung GmbH - ABB Sace T.M.S. S.p.A (prototype).

Claims (1)

A two-position electromagnet consisting of the fixed part of the magnetic circuit, the moving part, two coils and permanent magnets, characterized in that the fixed part of the magnetic circuit consists of coaxially arranged parts — a cylindrical core with a cylindrical hole and an annular protrusion in the middle part and an annular body, the ends of which are parallel to each other and perpendicular to the axis of the fixed part, the inner diameter of the annular body exceeds the outer diameter of the annular protrusions on the core, the parts of the fixed part are interconnected using non-magnetic parts located in the gap between the annular protrusion of the core and the housing, and these parts in azimuth only partially fill the gap, the coils are located between the core and the housing on both sides of the annular protrusion on the core, constant the magnets are located outside the part of the gap between the annular protrusion of the core and the housing occupied by non-magnetic parts, and the movable part consists of a non-magnetic rod located in the core hole, and the axial size of the rod part with a diameter equal to the diameter of the hole in the core exceeds the axial size of the fixed part of the magnetic circuit by the amount of travel of the movable part, and two disk-shaped anchors coaxial with the rod, fixed at the ends of the rod part with a diameter equal to the diameter of the hole in the core .

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