KR20020078666A - Reciprocating motor - Google Patents

Abstract

PURPOSE: A reciprocating type motor is provided to prevent a vibrating effect of a stator in an operating process of a motor by fixing a part or all parts of lamination sheets of the stator to each other. CONSTITUTION: A stator is formed with a bobbin(50), a terminal portion(60), a core portion(70), a fixing portion(80), and a plurality of inner cores(20). The bobbin(50) is combined with a winding coil(30). The terminal portion(60) has a connector(61) which is electrically connected with the winding coil(30). The core portion(70) is formed by laminating a multitude of lamination sheets(71). The fixing portion(80) is used for preventing a vibrating effect between the lamination sheets(71) when a flux is applied to the core portion(70). The inner cores(20) are inserted in a predetermined interval within the core portion(70).

Description

Reciprocating Motors {RECIPROCATING MOTOR}

The present invention relates to a reciprocating motor, and more particularly to a reciprocating motor that can prevent the stator of the stator made of a laminate in which the winding coil is inserted during operation of the motor.

In general, a motor is a device for converting electrical energy into kinetic energy, and such a motor is classified into a rotary motor for converting electrical energy into rotary motion and a reciprocating motor for converting electrical energy into linear reciprocating motion.

The motor is used in various fields as a power source. In particular, home appliances are installed in almost all products such as refrigerators, air conditioners, washing machines, fans. The refrigerator and the air conditioner may be used to rotate a blower fan, but may be mounted on a compressor of a refrigerating cycle apparatus constituting the refrigerator and the air conditioner and used as a power source.

FIG. 1 illustrates an example of the reciprocating motor under the present applicant's research and development. As shown in the drawing, the reciprocating motor has an outer core 10 and an outer core 10 having a cylindrical shape. Stator (S) consisting of an inner core (Inner Core) 20 formed to be inserted into the interior of the winding coil 30 and the permanent magnet 41 coupled to the outer core 10, the permanent magnet 41 It is configured to include a mover 40 is inserted to be movable between the outer core 10 and the inner core 20 is configured to include. The winding coil 30 may be coupled to the inner core 20.

In the reciprocating motor as described above, when a current flows in the winding coil 30, a flux is formed around the winding coil 30 by the current flowing in the winding coil 30, and the flux is the outer core 10. ) And the inner core 20 to form a closed loop. The permanent magnet is forced in the axial direction by the interaction of the flux flowing through the stator with the magnetic flux formed by the permanent magnet 41 so that the mover 40 is formed between the outer core 10 and the inner core 20. The linear motion in the axial direction, the alternating direction of the current applied to the winding coil 30 alternately the linear movement of the mover 40.

The outer core 10 and the inner core 20 constituting the stator S in the reciprocating motor are radially stacked such that a plurality of lamination sheets 11 and 21 formed of thin plates of a predetermined shape have a cylindrical shape. It consists of a laminated body. The winding coil 30 is mounted in the outer core 10 or the inner core 20 constituting the stator S, and when the current is applied to the winding coil 30, the flux due to the applied current is Electrical insulation and stator (S) to be formed should be made, and the coil is wound around the bobbin (50) formed in an annular shape by the insulating material for electrical insulation and simplicity of production.

The bobbin 50 has an annular groove in which a coil is wound inside an annular body formed in an annular shape to have a predetermined diameter, and is connected to an external power terminal on the side of the bobbin 50 which is the annular body. Is formed. The winding coil 30 is formed by winding a coil in multiple layers in an annular groove of the bobbin 50, and the wound coil is connected to a connector 52 provided in the terminal part 51.

And the structure that the bobbin 50 is coupled to the inner core 20 or the outer core 10 constituting the stator, as shown in Figure 3, the inner core 20 or the outer core to the bobbin 50 A plurality of lamination sheets 11 and 21 constituting the (10) is made in a form stacked radially. The presented figure shows a structure in which the bobbin 50 wound around the winding coil 30 is mounted on the outer core.

In this case, the lamination sheets 11 stacked along the bobbin 50 may be stacked in a cylindrical shape so as to start from one side of the terminal portion 51 and reach the other side of the terminal portion 51. The terminal portion 51 is formed in a trapezoidal shape in cross section in order to increase the lamination density of the lamination sheet 11. The lamination sheet 11 is formed in a tracer shape and the lamination sheet 11 formed in the tracer shape are alternately stacked on both sides along the bobbin 50 to form a cylindrical shape. The laminate laminated by the plurality of lamination sheets 11 is fixed by a separate fastening means (K).

However, the conventional reciprocating motor as described above is supplied while changing the direction of the current applied to the winding coil 30 during operation so that the direction of the flux formed in the stator (S) is formed while changing the Electromagnetic force is generated between the lamination sheet 11 constituting the inner core 20 and the outer core 10 to cause the lamination sheets 11 to vibrate. Due to such vibration, the lamination sheets 11 adjacent to each other due to the magnetic circuit structure of the inner core 20 and the outer core 10 of the stator do not collide with each other by the repulsive force of each other, but the lamination sheets adjacent to the terminal portion 52. In the case of (11), as shown in Fig. 4, the force that the lamination sheet 11 is pushed toward the terminal portion 52 side acts so that the vibration of the stator S occurs as well as the lamination sheet 11 ) Collides with the terminal portion 51, causing a crash noise.

SUMMARY OF THE INVENTION An object of the present invention devised in view of the above problems is to provide a reciprocating motor capable of preventing the stator of a stator made of a laminate into which a winding coil is inserted during operation of the motor.

1,2 is a front sectional view and a partial side view showing an example of a typical reciprocating motor;

3 is a cross-sectional view showing a process of laminating a lamination sheet on a bobbin constituting the reciprocating motor;

4 is a front view showing a shaking state of the main part of the reciprocating motor stator;

5, 6 is a front sectional view and a partial side view showing an example of the reciprocating motor of the present invention;

7,8,9,10,11,12,13,14,15 are partial front views each showing another embodiment and modification of the reciprocating motor of the present invention;

** Description of the symbols for the main parts of the drawings **

30; Winding coil 50; Bobbin

60; Terminal section 61; connector

70; Core portion 71; Lamination sheet

80; Fixing part 81; Fixing member

82; Binder 83; Resin

84; Insertion member 85; Rubber member

86; Fixed annular ring 86a; home

87; Welding line 88; Bonding member

In order to achieve the object of the present invention as described above, a bobbin coil is wound therein, and a terminal portion having a connector integrally formed with the bobbin and electrically connected to a winding coil wound at the bobbin therein; The lamination sheet to prevent the shaking between the core portion consisting of a plurality of lamination sheets radially laminated so as to form a cylindrical shape around the bobbin and a plurality of lamination sheets constituting the core portion when flux flows in the core portion. A reciprocating motor is provided which comprises a fixing portion for fixing all or a part of them to each other.

Hereinafter, the reciprocating motor of the present invention will be described according to the embodiment shown in the accompanying drawings.

5 and 6 illustrate an embodiment of the reciprocating motor of the present invention. Referring to this, the reciprocating motor of the present invention includes a stator S forming a flux by a current supplied thereto and the stator. (S) It is comprised so that the movable body 40 may be linearly reciprocally inserted inside and linearly reciprocates by interaction with the flux which the stator S generate | occur | produces.

The stator (S) is an annular bobbin (50) having a winding coil (30) coupled therein, and is formed integrally with the bobbin (50) and a winding coil (30) wound around the bobbin (50) therein. A terminal portion 60 having a connector 61 electrically connected to the core), and a core portion 70 in which a plurality of lamination sheets 71 are radially stacked so as to form a cylindrical shape around the bobbin 50; When the flux flows in the core portion 70, the fixing portion for fixing the entirety of the lamination sheet 71 to each other to prevent shaking between a plurality of lamination sheets 71 constituting the core portion 70 ( 80 and an inner core 20 inserted into the core part 70 at a predetermined interval.

The lamination sheet 71 constituting the core portion 70 is formed of a thin plate of a translator type and the translator type lamination sheet 71 is laminated in zigzag alternately with each other on both sides of the bobbin, but one of the terminal portion 60 Stacked from the side to the other side. At this time, the lamination sheet 71 is a portion positioned to surround the outer surface and the side of the bobbin 50 forms a pass portion (71a) through which the flux flows and the end portion located on the lower side of the side surface of the bobbin 50 The pole part 71b which forms this pole is formed. The core part 70 which consists of a laminated body of the lamination sheet 71 is fixed by the coupling ring K. As shown in FIG.

The terminal portion 60 is formed in a fan shape so that the lamination sheet 71 is densely stacked. The bobbin 50 and the terminal portion 60 are formed of an insulating material.

The fixing part 80 is composed of a fixing member 81 of a predetermined shape.

As a modification of the fixing part 80, as shown in FIG. 7, the fixing part 80 is provided over a part of the core part 70. That is, the fixing member 81 is provided between both side surfaces of the terminal portion 60 and the lamination sheet 71 facing both sides thereof.

The mover 40 is coupled to the magnet holder 41 and the magnet holder 41 formed in a cylindrical shape that is formed to be inserted between the core portion 70 and the inner core 20 and the core portion 70. ) And a permanent magnet 42 located between the inner core 20.

The configuration as described above, first, when the direction of the current flows alternately in the winding coil 30, the flux in which the directions alternate in the core portion 70 and the inner core 20 constituting the stator 40 by the current alternately Is formed and the mover 40 is linearly reciprocated by the interaction between the flux and the permanent magnet 42 constituting the mover 40.

A plurality of lamination sheets constituting the core part 70 when flux flows to the core part 70 constituting the stator S and the inner core 20 by applying current to the winding coil 30 in the above process. Flowing through the 71 and the pushing force between the lamination sheet 71 by the magnetic circuit formed in the lamination sheet 71 is acting.

As such, the lamination sheets 71 are moved by the pushing force between the lamination sheets 71, but the lamination sheets 71 are moved between the lamination sheets 71 by the fixing part 70 positioned between the lamination sheets 71. The collision between the lamination sheet 71 and the terminal part 60 is prevented from occurring or shaking. That is, a fixing part 80, that is, a fixing member 81 is inserted between the terminal part 60 and the lamination sheet 71 adjacent to the terminal part 60 and between the lamination sheet 71 to insert the lamination sheet 71. By suppressing the movement between the) to prevent the collision between the lamination sheet 71 or between the lamination sheet 71 and the terminal portion 60.

On the other hand, as another embodiment of the present invention, as shown in Figure 8, when the flux flows in the core portion 70, the vibration between the plurality of lamination sheet 71 constituting the core portion 70 It is made by bonding an adhesive 82 between the lamination sheets 71 to prevent it. The adhesive 82 is applied to be disposed on the side of the lamination sheet 71 constituting the core portion 70. The adhesive 82 is applied between both side surfaces of the terminal portion 60 and the lamination sheet 71 facing each side thereof, and the lamination sheet 71 positioned on both sides of the terminal portion 60 is the terminal portion 60. It is preferable to be attached to both sides of each. In addition, the adhesive 82 is not limited to both side surfaces of the terminal part 60, and may be coated and bonded over the entire lamination sheet 71 constituting the core part 70.

When the adhesive 82 is applied between the lamination sheets 71 constituting the core portion 70, the adhesive 82 filled between the lamination sheets 71 flows out to cause the inner core 20 and the core to flow. If stuck between the parts 70 may interfere with the movement of the mover 40 located therebetween, except for the pawl portion 71b of the lamination sheet 71, that is, the pass portion 71a side of the lamination sheet. It is preferably applied to.

The adhesive is preferably selected from materials suitable for the refrigerant filled in the compressor when the reciprocating motor is mounted on the compressor.

In the structure as described above, an adhesive 82 is applied between the lamination sheets 71 constituting the core portion 70 and between the terminal portion 60 and the lamination sheet 71 adjacent to the terminal portion 60. Adhesively fixing between the lamination sheets 71 or bonding the lamination sheet 71 facing the terminal portion 60 and the terminal portion 60, respectively, thereby inhibiting the movement between the lamination sheets 71 to prevent the The collision between the lamination sheets 71 or between the lamination sheets 71 and the terminal portion 60 is prevented from occurring.

In addition, as another embodiment of the present invention, as shown in Figure 9, when the flux flows in the core portion 70, the vibration between the plurality of lamination sheet 71 constituting the core portion 70 The fixing part 80 formed by molding with the resin material 83 between the lamination sheets 71 is provided to prevent it. The fixing portion, that is, the resin material 83, is inserted to be disposed on the side of the lamination sheet 71 constituting the core portion 70. The resin material 83 is inserted over the entire lamination sheet 71 constituting the core portion 70, or between the lamination sheets 71 facing both side surfaces of the terminal portion 60 and both sides thereof, respectively. Is inserted.

As described above, the resin material 83 is molded between the lamination sheets 71 constituting the core portion 70 and between the terminal portion 60 and the lamination sheet 71 adjacent to the terminal portion 60. The lamination sheet 71 is inserted into and fixed between the lamination sheets 71 or the lamination sheet 71 facing the terminal portion 60 and the terminal portion 60 is suppressed so that the movement between the lamination sheets 71 is suppressed. The collision between the lamination sheets 71 or between the lamination sheets 71 and the terminal portion 60 is prevented from occurring.

In addition, as another embodiment of the present invention, as shown in Figure 10, at least one between the lamination sheet 71 constituting the core portion 70 so that the inner diameter side of the core portion 70 is in close contact with each other The above insertion member 84 is inserted and made. The insertion member 84 is formed in the shape of a wedge and is fixed between the terminal portion 60 and the lamination sheet 71 of the core portion 70 adjacent to the terminal portion 60. The insertion member 84 is made of a metal material. In addition, as a modification of the insertion member 84, the insertion member 84 is made of an insulating material.

As described above, the insertion member 84 is sandwiched between the lamination sheets 71 constituting the core portion 70 and between the terminal portion 60 and the lamination sheet 71 adjacent to the terminal portion 60. Fixed to fix between the lamination sheets 71 or to fix the lamination sheet 71 facing the terminal portion 60 and the terminal portion 60, respectively, thereby suppressing movement between the lamination sheets 71 The collision between the lamination sheets 71 or between the lamination sheets 71 and the terminal portion 60 is prevented from occurring.

In another embodiment of the present invention, as shown in FIG. 11, when a flux flows in the core part 70, the vibration between the plurality of lamination sheets 71 constituting the core part 70 is reduced. The rubber members 85 are sandwiched between the lamination sheets 71 so as to prevent them.

The rubber member 85 is inserted to be disposed on the side of the lamination sheet 71 constituting the core portion 70. The rubber member 85 is fitted over the entire lamination sheet 71 constituting the core portion 70 or between the lamination sheets 71 facing both sides of the terminal portion 60 and both sides thereof. Lose. The rubber member 85 is preferably positioned so as not to protrude inward to the pole portion 71b side of the core portion 70.

In addition, as a modification of the rubber member, as shown in FIG. 12, rubber members 85 sandwiched between the lamination sheets 71 are connected to each other. The connection portion 85a of the rubber member 85 and the rubber member 85 is positioned at the side of the core portion 70.

As described above, the rubber member 85 is interposed between the lamination sheets 71 constituting the core portion 70 and between the terminal portion 60 and the lamination sheet 71 adjacent to the terminal portion 60. The lamination sheet 71 is fixed between the lamination sheets 71 or the lamination sheet 71 facing the terminal portion 60 and the terminal portion 60 is restrained, thereby inhibiting the movement between the lamination sheets 71. The collision between the 71 or between the lamination sheet 71 and the terminal portion 60 is prevented from occurring.

In addition, as another embodiment of the present invention, as shown in FIG. 13, a plurality of grooves 86a are formed at the sides of each lamination sheet 71 constituting the core portion 70 and the lamination sheet 71 is formed. ) Is formed by inserting annular rings 86 into the grooves 86a, respectively. That is, the groove 86a is formed in each lamination sheet 71 constituting the core portion 70, so that an annular fixing groove is formed on the side surface of the core portion 70 composed of the lamination sheets 71. And an annular fixing ring 86 is inserted into the annular fixing groove. The fixing ring 86 is preferably coupled to be located on the opposite side of the coupling ring K coupled to the core portion 70, that is, the pole portion 71b of the core portion 70.

As described above, since the lamination sheets 71 constituting the core portion 70 are fixed by the fixing ring 86, when the flux flows in the core portion 70, the movement between the lamination sheets 71 is performed. By suppressing this, collision between the lamination sheets 71 or between the lamination sheets 71 and the terminal portion 60 is prevented from occurring.

On the other hand, the fixing ring 86 may be coupled to the plurality of core portion 70.

In addition, as another embodiment of the present invention, as shown in Figure 14, when the flux flows in the core portion 70, the vibration between the plurality of lamination sheet 71 constituting the core portion 70 To prevent the core part 70 is provided with a welding line 87 by welding. The welding line 87 bonds the lamination sheets 71 constituting the core part 70 to each other to fix the lamination sheets 71.

As described above, since the lamination sheets 71 constituting the core part 70 are fixed to each other by the welding line 87 by welding, the lamination sheet 71 is suppressed by suppressing the movement between the lamination sheets 71. ), Or collision between the lamination sheet 71 and the terminal portion 60 is prevented.

In addition, as another embodiment of the present invention, as shown in Figure 15, the coil is wound therein and the bobbin 50 is formed integrally with the bobbin 50, the winding on the bobbin 50 therein The bobbin 50 includes a terminal portion 60 having a connector 61 electrically connected to the wound coil 30, and a plurality of lamination sheets 71 having pole portions 71b constituting poles on both sides thereof. Bonding member 88 between the core part 70 which is laminated radially to form a cylindrical shape as a center, and the lamination sheet 71 so that the whole lamination sheet 71 which comprises the core part 70 is mutually fixed. It is configured to include a fixing portion 80 made by filling.

The bonding member 88 is filled in the side portion of the lamination sheet 71 or the opposite side of the pawl portion 71b.

On the other hand, the bonding member 88 is filled between the lamination sheet 71 adjacent to the terminal portion 60 as a modification thereof. Another modification of the bonding member is by a film formed by varnish treatment.

As described above, since the lamination sheets 71 constituting the core portion 70 are fixed by the bonding member 88, the movement between the lamination sheets 71 is performed when flux flows in the core portion 70. It is suppressed to prevent a collision between the lamination sheets 71 or between the lamination sheets 71 and the terminal portion 60.

As described above, the reciprocating motor according to the present invention not only prevents a plurality of lamination sheets constituting the stator from shaking or colliding with each other due to the flux flowing in the stator during operation, but also adjacent to the terminal portion and the terminal portion. By preventing the collision between the lamination sheet to minimize the noise generated during the operation as well as to prevent damage to the parts there is an effect that can increase the reliability of the product.

Claims (18)

The bobbin is wound around the bobbin including a bobbin having a coil wound therein, a terminal part having a connector formed integrally with the bobbin and electrically connected to a winding coil wound at the bobbin therein, and a pole forming a pole. A plurality of lamination sheets are fixed to each other so as to prevent shaking between a core part including a plurality of lamination sheets radially stacked to form a cylindrical shape, and lamination sheets constituting the core part when flux flows in the core part. Reciprocating motor, characterized in that configured to include a fixing. The reciprocating motor according to claim 1, wherein the fixing part is a fixing member having a predetermined shape provided between the lining sheets adjacent to the terminal part. The reciprocating motor according to claim 1 or 2, wherein the fixing part is formed by applying an adhesive between the lamination sheets so that the lamination sheets are mutually bonded to each other. 4. The reciprocating motor as claimed in claim 3, wherein the fixing part is disposed at the side of the lamination sheet. The reciprocating motor according to claim 1 or 2, wherein the fixing part is formed by molding a resin material so that the lamination sheets are bonded to each other. The reciprocating motor according to claim 1, wherein the fixing part is formed by inserting at least one insertion member between lamination sheets constituting the core part such that the inner diameter side of the core part is in close contact with each other. 7. The reciprocating motor according to claim 6, wherein the insertion member is sandwiched and fixed between the lamination sheets of the core portion and the adjacent core portion. 7. The reciprocating motor according to claim 6, wherein the insertion member is made of metal. 7. The reciprocating motor as claimed in claim 6, wherein the insertion member is an insulating material. The reciprocating motor according to claim 1, wherein the fixing part is made of a rubber member that is fitted between the lamination sheets constituting the core part. 11. The reciprocating motor of claim 10, wherein the rubber members are interconnected. The reciprocating motor according to claim 1, wherein the fixing part forms two or more grooves at predetermined intervals on the side of the core part, and two circular rings are inserted into the grooves, respectively. The reciprocating motor according to claim 1, wherein the fixing part comprises a lamination sheet constituting the core part and a welding line welded with the lamination sheet. A bobbin having a coil wound therein, a terminal part having a bobbin formed integrally with the bobbin, and a connector part connected to a winding coil wound around the bobbin in a timely manner, and having a cylindrical shape with respect to the bobbin A core portion formed by laminating a lamination sheet radially, and a fixing portion formed by forming a plurality of grooves on the sides of each lamination sheet constituting the core portion and inserting annular rings into the grooves so that the lamination sheets are fixed. Reciprocating motor, characterized in that configured by. A plurality of laminations including a bobbin having a coil wound therein, a terminal part having a connector formed integrally with the bobbin and electrically connected to a winding coil wound at the bobbin therein, and pole portions forming poles at both sides thereof Including a core formed by laminating a sheet radially so as to form a cylindrical shape around the bobbin and a bonding member filled between the lamination sheets to secure all or a part of the lamination sheets constituting the core. Reciprocating motor characterized in that the configuration. The reciprocating motor as claimed in claim 15, wherein the bonding member is filled in a side portion of the lamination sheet or an opposite portion of the pawl portion. The reciprocating motor according to claim 15, wherein the bonding member is filled between lamination sheets adjacent to the terminal portion. A plurality of laminations having a bobbin with a coil wound therein, a terminal part having a connector integrally formed with the bobbin and electrically connected to a winding coil wound at the bobbin therein, and pole portions forming poles at both sides thereof A reciprocating motor comprising a core part formed by radially stacking a sheet in a cylindrical shape with respect to the bobbin, and a fixing part which extends the terminal part to fix the lamination sheet facing the terminal part. .