RU2485662C1 - Reciprocable electromagnetic motor - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: electromagnetic motor contains cylindrical induction coil consisting of magnetic core and excitation winding located in its circular groove; forward and reverse stroke armatures opposite to each other in coaxial relationship; return spring installed in the axial channel formed by end blind grooves in forward and reverse stroke armatures. Forward and reverse stroke armatures are made as disc and cylindrical parts interconnected rigidly. Cylindrical parts have diameters of different values. In cylindrical part of the forward stroke armature there is an internal blind groove which diameter is bigger than the diameter of cylindrical part of the reverse stroke armature, and it is capable to move along inner grove of the forward stroke armature. Disc parts of the armatures are oriented towards different poles of cylindrical induction coil. In the reverse stroke armature there is an axial bore with axial rod of the forward stroke armature located in it.

EFFECT: reduction of vibration level for electric motor housing, increase in performance and economical operation.

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Description

The invention relates to the field of electromechanics, and in particular to electric machines reciprocating, at the same time oncoming traffic and electric drives based on them.

A known electromagnetic motor, consisting of a cylindrical stator with a winding, a disk armature, two identical working air gaps, a return spring, a casing and two coaxial cylinders mounted on the inner plane of the disk, set in motion the working body of the press (AS USSR No. 8555888, IPC Н02К 33/02, published on August 15, 1981). Such an engine is designed for direct power action and its stator is fixed from the inverse effect of force on the engine by the foundation or a special bed on which it is installed.

The disadvantage of this analogue is the inability to use in small electromechanical devices and in manual power tools, because the engine during direct operation has the inverse effect of the recoil force, which creates a strong vibration of the engine housing and a complex structure.

A linear electromagnetic press drive is also known (RF Patent No. 2193943, IPC B21J 7/30, B30B 1/42, publ. 10.12.2002), where the electromagnetic motor contains a stator with a winding located in it and an armature guiding the casing with emphasis and return spring. An anchor consists of two parts moving relative to each other. One part is a glass, and the second is a cylindrical core located inside the glass. The cross-sectional area of the glass is less than the cross-sectional area of the cylindrical glass. There are beads at the top of the glass and core. The anchor in the initial position is installed with the condition that the distance between the flanges of the core and the focus of the guide casing is less than the magnitude of the working stroke of the armature.

The disadvantage of this analogue, as well as the previous one, is the lack of the possibility of its use in hand-held power tools due to strong vibration.

Also known is a linear reciprocating motor (AS USSR No. 1725330, IPC Н02К 33/00, H01F 7/16, publ. 04/07/1992), containing a stator with a magnetic circuit and a winding, in the cavity of which an anchor with axial blind hole in which the adjusting screw is placed to regulate the amplitude of the motor armature travel, the return spring.

The disadvantage of this analogue is the inability to use it in hand-held power tools due to strong vibration.

The closest in technical essence and the achieved effect is an electromagnetic drive of reciprocating motion (AS USSR No. 1453544, IPC Н02К 33/02, published on January 23, 1989), containing a cylindrical inductor consisting of a magnetic circuit and a winding located in the annular groove of the magnetic circuit, while the inner cylindrical surface of the cylinder is formed by the inner cylindrical surfaces of the poles of the magnetic circuit and the winding, and a coaxially located movable armature, consisting of two parts, containing ferromagnetic electrically conductive elements, a return spring and two identical parts complementing each other to a full cylinder, each of which consists of a ferromagnetic and mounted on its end located inside the inductor, conductive elements, while the armature is symmetrical with respect to the inductor, and the return spring is installed in the axial the channel of the anchor, formed by blind end grooves in its parts, and rests at its ends on different parts of the anchor.

The disadvantage of the prototype is a low-efficiency magnetic system, because the armature is not a solid ferromagnetic body, but consists of two longitudinally separated parts oriented towards their oncoming movement, therefore the magnetic flux of the winding is divided into moving parts, which reduces the efficiency of the motor. In addition, the design of the prototype is far from practical application and requires serious revision.

The objective of the present invention is to reduce the level of vibration of the motor housing, increasing productivity and efficiency.

The technical result consists in increasing the level of safety during operation of a linear electromagnetic reciprocating motor, in reducing the power consumption due to the pulse power of the electromagnetic motor, in increasing labor productivity and economy.

The problem is achieved in that in the electromagnetic motor of the reciprocating motion, containing a cylindrical inductor, consisting of a magnetic circuit and an excitation winding, located in the annular groove of the magnetic circuit, coaxially opposed forward and reverse armature, a return spring installed in the axial channel formed by the end deaf grooves in the forward stroke anchor and reverse stroke anchor, according to the proposed technical solution, the forward stroke anchor and reverse stroke anchor are made in in the form of rigidly interconnected disk and cylindrical parts, while the cylindrical parts have diameters of excellent magnitude, and in the cylindrical part of the forward armature there is an internal blind groove, the diameter of which is larger than the diameter of the cylindrical part of the backward armature, which is made with the possibility of movement along the inner groove forward stroke anchors, disk parts of the anchors are directed to different poles of the cylindrical inductor, while the forward stroke anchor has an axial rod, and the backward anchor has etsya axial hole, wherein the axial rod is movably forward stroke of the armature.

Comparative analysis with the prototype shows that the claimed electromagnetic reciprocating motor is characterized in that it contains two counter-directional ferromagnetic anchors of the same mass, where the disk parts of the anchors are directed to different end poles of the cylindrical magnetic circuit of the inductor, while the axial rod of the forward-running armature passes through through axial hole of the return armature.

Thus, the claimed electromagnetic reciprocating motor meets the criteria of the invention of "novelty."

Comparison of the proposed solution not only with the prototype, but also with other technical solutions in this technical field did not reveal the signs that distinguish the claimed solution from the prototype, and the introduction of two counter-directional ferromagnetic anchors and axial onward movement of the forward armature in the through axial hole backward anchors made it possible to conclude that the technical solution meets the criterion of "significant differences".

The invention is illustrated in the drawing, where figure 1 shows a longitudinal section of an electromagnetic motor reciprocating, where the positions indicated:

1 - a cylindrical magnetic circuit of the inductor;

2 - field winding;

3 - direct forward anchor;

4 - backward anchor;

5 - disk part of the forward stroke armature;

6 - cylindrical part of the forward stroke armature;

7 - disk part of the backward anchor;

8 - cylindrical part of the backward anchor;

9 - internal blind groove anchor forward stroke;

10 - axial rod of the forward armature;

11 - through axial hole of the return armature;

12 - end blind groove anchors forward and reverse;

13 - a return spring;

14 - pole of the inductor for the forward armature;

15 - pole of the inductor for the return armature.

The electromagnetic reciprocating motor comprises a cylindrical inductor consisting of a magnetic circuit 1 with a field winding 2 located in an annular groove of the magnetic circuit, two coaxially opposed forward armature 3 and reverse armature 4, which are made in the form of a rigidly connected disk part 5 and the cylindrical part 6 of the forward armature 3 and the disk part 7 and the cylindrical part 8 of the reverse armature 4 (FIG. 1). The cylindrical parts 6, 8 of the forward armature 3 and the reverse armature 4, respectively, have diameters of different magnitude. The cylindrical part 6 of the forward armature 3 has an internal blind groove 9 of depth 2δ, the diameter of which is larger than the diameter of the cylindrical part 8 of the backward armature 4, and provides a gap between them. In this case, the cylindrical part 8 of the backward anchor 4 is made with the possibility of moving the forward anchors 3 in the inner blind groove 9. The forward anchor 3 has an axial rod 10, and the reverse anchor 4 has a through axial hole 11 in which the axial rod 10 of the forward stroke armature 3. The diameter of the axial rod 10 of the forward stroke armature 3 and the diameter of the through axial hole 11 of the reverse stroke armature 4 are made, for example, with a landing fit. Both anchors in the inner cylindrical parts have endless blind grooves 12, in the axial channels of which a return spring is installed 13. The disk parts 5, 7 of the armature of the forward stroke 3 and the reverse stroke 4 are respectively directed to and are separated from the different poles 14, 15 of the cylindrical magnetic circuit of the inductor 1 at a distance δ equal to the working clearance. The inner blind groove 9 of the forward stroke anchor 3 has a depth of at least double working clearance 2δ. The forward stroke armature 3 is equal in mass to the reverse stroke anchor 4.

The electromagnetic motor reciprocating movement operates as follows. When a voltage pulse is applied to the field winding 2, a magnetic flux arises, which causes the oncoming movement of the forward travel armature 3 and the reverse travel 4 armature, while the forward travel armature 3 and the reverse motion armature 4 are synchronously attracted by their disk parts 5 and 7 to the poles 14 and 15 of the cylindrical magnetic inductor 1, the oncoming movement of the anchors. When moving, the cylindrical part 8 of the return armature 4 enters the inner blind groove 9 of the forward armature 3. As a result of the oncoming movement of the forward armature 3 and reverse 4, the return spring 13 is compressed, located in the blind end grooves 12 of the direct 3 arm and reverse 4 , while the return armature 4 moves with its through axial hole 11 along the axial shaft 10 of the forward armature 3. When releasing voltage from the field winding 2, the forward arm 3 and the reverse arm 4 under the action of the compressed return force hydrochloric spring 13 returning to its original position. When applying a series of voltage pulses to the field winding 2, the electromagnetic reciprocating motor operates in a pulsed mode without vibration.

The presence of anchors forward 3 and reverse 4 having cylindrical 6, 8 and disk parts 5, 7, respectively, allows you to more fully use the useful magnetic flux passing through both anchors 3, 4 and the cylindrical magnetic core of inductor 1, creating the greatest force on the axial rod 10 forward stroke anchors 3. In addition, the design of counter-directional movements of the anchors eliminates strong vibration of the engine and increases its reliability.

The execution of the forward stroke armature 3 equal in weight to the reverse stroke armature 4 contributes to the fact that when a voltage pulse is applied to the field winding 2, a magnetic flux is generated and the mechanical attractive force of the anchors 3, 4 is evenly distributed to the forward stroke armature 3 and the reverse stroke 4, which also contributes to reduce vibration of the motor housing and increase its reliability.

Thus, the level of safety during operation of the electromagnetic reciprocating motor increases, power consumption due to its pulse power decreases, labor productivity and profitability increase, and the workplace is also more environmentally friendly.

Claims (1)

An electromagnetic reciprocating motor containing a cylindrical inductor consisting of a magnetic circuit and an excitation winding located in an annular groove of the magnetic circuit, coaxially opposed forward and reverse armature, a return spring installed in the axial channel formed by end blind grooves in the forward motion armature and backward anchor, characterized in that the backward anchor and backward anchor are made in the form of a disk and cylindrical part rigidly interconnected d, while the cylindrical parts have diameters of different magnitude, and in the cylindrical part of the forward armature there is an internal blind groove, the diameter of which is larger than the diameter of the cylindrical part of the backward armature, which is arranged to move along the inner groove of the forward armature, the disk parts of the anchors are directed to different poles of the cylindrical inductor, while the forward anchor has an axial rod, and the return anchor has an axial hole in which the axial rod is movably The anchor is straight forward.