RU2526852C2 - Electromagnetic motor (versions) - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is related to the sphere of electric engineering, in particular, to electromagnetic motors, and may be used for impulse devices with reciprocating motion of actuators. The suggested electromagnetic motor comprises a cylindrical magnet core consisting of a case, plunger and a flange connecting them, a winding placed at the plunger and a flat and direct external armature with circular ferromagnetic shunt. In a longitudinal channel of the above plunger there is a spring with a guide pin capable of axial motion; the pin is fixed rigidly to the flat and direct armature. According to the first version of this invention along length of outer and inner diameter of the circular ferromagnetic shunt there are collars with a pitch equal to a pitch of the corresponding coupled collars formed at outer diameter of the plunger and inner diameter of the case respectively. According to the second version in the suggested electromagnetic motor collars are made along length of inner diameter of the circular ferromagnetic shunt and coupled by diameter to the corresponding collars formed at outer diameter of the plunger. According to the third version in the suggested electromagnetic motor collars are made along length of outer diameter of the circular ferromagnetic shunt and coupled by diameter to the corresponding collars formed at inner diameter of the case. In any version of the electromagnetic motor the above collars form the toothed area of the magnet system.

EFFECT: increase of their reliability ensured by elimination of impact at the end of operating stroke between the flat and direct armature and the case of magnet core notwithstanding duration of voltage pulse supply to the winding and time of the armature motion.

3 cl, 3 dwg

Description

The invention relates to electrical engineering, in particular to electromagnetic motors, and can be used for pulse devices with reciprocating movement of the working bodies.

Known electromagnetic engine [A. p. 855888, MKL. H2K 33/02. Electromagnetic motor. / V.Yu. Kozhevnikov, V.N. Fedonin, G.G. Ugarov, A.V.Lvitsyn. - No. 2766131 / 24-07; declared 05/10/79; publ. 08/15/81; Bull. No. 30. - 2 p.], Containing a cylindrical magnetic circuit, a winding, a flat external forward anchor with a ferromagnetic shunt made in the form of a cylinder.

The disadvantages of this technical solution include the impact of the armature on the casing of the magnetic circuit at the end of the stroke, which reduces the reliability of the electromagnetic motor due to the mechanical interaction of the armature with the casing of the magnetic circuit.

Closest to the claimed invention in technical essence is an electromagnetic motor [A. p. 2089995 of the Russian Federation, IPC 6 Н02K 33/02, H01F 7/16. Electromagnetic motor. / V.N. Fedonin, G.A. Vitmaer, S.P. Podoprigora, E.M. Garanin. - No. 95108453/07; declared 06/05/95; publ. 09/10/97. - 10 p.], Containing a cylindrical magnetic circuit, consisting of a housing, a core connecting their flanges, a winding located around the core, a flat external forward anchor with a ferromagnetic shunt made in the form of a ring. To mitigate shocks at the end of the stroke, a non-magnetic gasket is installed between the flat external linear anchor and the body of the magnetic circuit.

The disadvantages of this technical solution include the impact of the armature on the casing of the magnetic circuit at the end of the stroke if the duration of the voltage pulse to the winding exceeds or is comparable with the time of movement of the armature, which reduces the reliability of the electromagnetic motor due to mechanical interaction of the armature with the casing of the magnetic circuit.

The objective of the invention is to increase the reliability of the electromagnetic motor.

This task is achieved by the fact that in an electromagnetic motor containing a cylindrical magnetic circuit, consisting of a housing, a core and a connecting flange, a winding located on the core and a flat external forward armature with a ring-shaped ferromagnetic shunt, ring protrusions are made along the length of the outer and inner diameters of the ring-shaped ferromagnetic shunt with a step equal to the step of the reciprocal annular protrusions mated in diameter, formed by the outer diameter of the core and the inner diameter of casing of the magnetic circuit.

Figure 1 shows a section of an electromagnetic motor (option 1), in which annular protrusions are made along the length of the outer and inner diameters of the ring-shaped ferromagnetic shunt with a step equal to the step of the reciprocal annular protrusions mated along the diameter of the core and the inner diameter of the casing magnetic circuit; figure 2 presents a section of an electromagnetic motor (2nd option), in which annular protrusions made along the length of the inner diameter of the annular ferromagnetic shunt are mated along the diameter of the mating annular protrusions formed along the outer diameter of the core; figure 3 presents a section of an electromagnetic motor (3rd option), in which annular protrusions made along the length of the outer diameter of the annular ferromagnetic shunt are mated along the diameter of the reciprocal annular protrusions formed along the inner diameter of the casing.

The electromagnetic motor (Fig. 1) contains a cylindrical magnetic circuit consisting of a housing 1, a core 2 and a flange 3 connecting them, a winding 4 located on the core and a flat external forward anchor 5 with an annular ferromagnetic shunt 6. Housing 1, core 2 and the flange connecting them 3 form the stator of the magnetic circuit. In the longitudinal channel of the core 2 there is a spring 7, inside of which with the possibility of axial movement a guide rod 8 is placed, rigidly connected with a flat linear armature 5. Along the outer and inner diameters of the ring-shaped ferromagnetic shunt 6, annular protrusions 9 and 10 are made with a step equal to the conjugate step the diameter of the mating annular protrusions 11 and 12 formed by the outer diameter of the core and the inner diameter of the housing, respectively. The annular protrusions 9, 10 and 11, 12, located perpendicular to the transmitted force, form the tooth zone of the magnetic system.

In the second embodiment (FIG. 2), in the electromagnetic motor along the length of the inner diameter of the annular ferromagnetic shunt 6, annular protrusions 10 are made with a step equal to the step of the diameter-conjugated reciprocal annular protrusions 11 formed along the outer diameter of the core 2. The annular protrusions 10 and 11 form a ring zone of the magnetic system.

In the third embodiment (FIG. 3), in the electromagnetic motor along the outer diameter of the annular ferromagnetic shunt 6, annular protrusions 9 are made with a step equal to the step of the counter-mating annular protrusions 12 formed along the inner diameter of the housing 1. The annular protrusions 9 and 12 form a ring zone of the magnetic system.

The electromagnetic motor operates as follows.

In the initial state, a flat external forward anchor 5 with a ferromagnetic shunt 6 and a guide rod 8 is extended from the stator of the magnetic circuit by the value of the maximum working stroke of the armature, determined by the initial position of the annular protrusions 9 and 10, made along the length of the outer and inner diameter of the annular ferromagnetic shunt, relative to the annular protrusions 11 and 12 formed by the inner diameter of the stator of the magnetic circuit.

When a voltage pulse is applied to the winding 4 (Fig. 1), an electric current flows through it, inducing a magnetic field, the magnetic lines of force of which are closed through the core 2, ring protrusions 11 made along the length of the outer diameter of the core 2, through the air gap, ferromagnetic ring protrusions 10 formed by the inner diameter of the ring-shaped shunt 6, the ring-shaped ferromagnetic shunt 6, annular protrusions 9, formed by the outer diameter of the ring-shaped ferromagnetic shunt 6, through the air gap, ring The protrusions 12 made on the inner diameter of the housing 1, the housing 1 and the flange 3.

In the embodiment of the electromagnetic motor (Fig. 2), the magnetic field lines induced by the electric current flowing through the winding 4 are closed through the core 2, ring protrusions 11 made along the length of the outer diameter of the core 2, through the air gap, ferromagnetic ring protrusions 10 formed along the inner diameter of the annular shunt 6, an annular ferromagnetic shunt 6, through the air gap, the housing 1 and the flange 3.

In the embodiment of the electromagnetic motor (Fig. 3), the magnetic lines of force induced by the electric current flowing through the winding 4 are closed through the core 2, the ring-shaped ferromagnetic shunt 6, the ring protrusions 9 formed along the outer diameter of the ring-shaped ferromagnetic shunt 6, through the air gap, the ring protrusions 12, made on the inner diameter of the housing 1, the housing 1 and the flange 3.

Under the influence of electromagnetic forces, a ring-shaped ferromagnetic shunt 6 is drawn into the stator cavity of the magnetic circuit by the amount of mismatch of the tooth zone. The direction of motion of the flat external forward anchor 5 with the ring-shaped ferromagnetic shunt 6 is determined by the initial position of the tooth zone of the elements on the ring-shaped ferromagnetic shunt 6 with respect to the tooth zone of the elements on the stator of the magnetic circuit.

The position in which the annular protrusions 9 and 10, made along the length of the outer and inner diameters of the ferromagnetic shunt, are located in the same plane as the conjugate mating annular protrusions 11 and 12 formed along the inner diameter of the stator of the magnetic circuit, which ensures magnetic balance of the system when the magnetic flux is in working the gap is maximum, and the resulting electromagnetic force is zero. Such a constructive solution eliminates collisions taking place in the prototype at the end of the working stroke between the flat external forward anchor and the body and the magnetic circuit.

Thus, the proposed technical solutions ensure the elimination of collisions at the end of the working stroke between the flat linear armature and the body of the magnetic circuit, regardless of the duration of the voltage pulse to the winding and the armature travel time, which improves the reliability of the electromagnetic motor.

Claims (3)

1. An electromagnetic motor containing a cylindrical magnetic circuit, consisting of a housing, a core and a connecting flange, a winding located on the core and a flat external forward anchor with an annular ferromagnetic shunt, characterized in that annular protrusions are made along the outer and inner diameters of the annular ferromagnetic shunt by a step equal to the step of the reciprocal ring protrusions mated in diameter, formed by the outer diameter of the core and the inner diameter of the casing ode. 2. An electromagnetic motor containing a cylindrical magnetic circuit, consisting of a housing, a core and a connecting flange, a winding located on the core and a flat external forward anchor with an annular ferromagnetic shunt, characterized in that annular protrusions are made along the length of the inner diameter of the annular ferromagnetic shunt, equal to the step of the diameter-mating mating annular protrusions formed along the outer diameter of the core. 3. An electromagnetic motor containing a cylindrical magnetic circuit, consisting of a housing, a core and a connecting flange, a winding located on the core and a flat external forward anchor with an annular ferromagnetic shunt, characterized in that annular protrusions are made along the length of the outer diameter of the annular ferromagnetic shunt, equal to the step mating in diameter of the reciprocal annular protrusions formed by the inner diameter of the body of the magnetic circuit.

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