KR100556817B1 - Stater structure for reciprocating motor - Google Patents

Abstract

The present invention relates to a stator structure of a reciprocating motor. The present invention relates to an outer stator having a winding coil, an inner stator having a predetermined gap inside the outer stator, and a magnet between the outer stator and the inner stator. In the reciprocating motor including a mover that linearly reciprocates by flux between the two stators, the inner stator is a cylindrical stator block produced by a powder metallurgy method using a soft magnetic composite; By constructing a stator laminated body that radially stacks a plurality of thin stator cores in a cylindrical shape and inserts and couples the outer or inner circumferential surface of the stator block, the assembly process of the stator is much simplified to increase productivity while using less expensive powder metal. Not only can the production cost rise excessively. In addition, the self-expansion area is enlarged to improve motor efficiency.

Further, by arranging the frame on both sides of the inner stator and fastening to the frame by fastening bolts through the inner stator, the outer stator as well as the inner stator can be firmly fixed to increase the reliability of the motor.

Description

Stator structure of reciprocating motors {STATER STRUCTURE FOR RECIPROCATING MOTOR}

1 is a cross-sectional view showing an example of a conventional reciprocating motor,

2 and 3 are a perspective view and a front view respectively showing examples of the inner stator of the conventional reciprocating motor,

Figure 4 is a perspective view showing the inner stator of the reciprocating motor of the present invention,

5 is a side view showing the present invention the inner stator,

6 is a cross-sectional view of fixing the present invention the inner stator together with the outer stator,

7 is a cross-sectional view taken along line "I-I" of FIG. 6;

Figure 8 is a cross-sectional view showing another embodiment of the present invention the inner stator.

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

100: inner stator 110,310: stator block

111: laminated body insertion groove 112,311: through hole

120,320: Stator stack 121,321: Stator core

210,220: Frame 211: Bolt hole

221: fastening groove 230: fastening bolt

The present invention relates to a stator of a reciprocating motor, and more particularly, to a stator structure of a reciprocating motor in which an inner stator is formed by mixing a laminate and a sintered body.

In general, a reciprocating motor is a deformation of a magnetic field of a three-dimensional motor (Magnet Field) into a flat plate shape, so that the mover assembly formed of a flat plate is also placed on the upper side of the stator assembly formed of a flat plate to move in a straight line according to the change of the magnetic field It is.

The reciprocating motor separates the stator assembly into a cylindrical outer stator and the inner stator, and arranges them so that they overlap with a predetermined gap, and moves the movable assembly between the outer stator and the inner stator, and the outer stator and the inner stator. The winding coil is mounted on one of the stators, and the magnet assembly is attached to the corresponding mover assembly so that the mover reciprocates axially by the flux of the winding coil.

1 is a cross-sectional view showing an example of a conventional reciprocating motor, Figures 2 and 3 are a perspective view and a front view showing an example of the inner stator of the conventional reciprocating motor, respectively.

As shown in the drawing, the conventional reciprocating motor includes a stator assembly 10 that forms a flux and a movable assembly 20 that reciprocates in a straight line according to the flux of the stator assembly 10.

The stator assembly 10 is formed in a cylindrical shape so as to be positioned at an outer side of the mover assembly 20 in a cylindrical shape, and at a predetermined inter-core distance inside the outer stator 11. The inner stator 12 is composed of.

The outer stator 11 forms a thin stator core in the shape of a "dimple" and radially laminates it on the outer circumferential surface of the bobbin (unsigned) wound around the winding coil C, or "remembers" the thin stator core (unsigned). It is also possible to form a core block (unsigned) formed by stacking a plurality of sheets each by fabricating a "and a" reverse memory "shape and then laminating them in a symmetrical radial manner.

The inner stator 12 is formed by forming a rectangular stator core 12a in a rectangular plate shape as shown in FIG. 2, or forming a thin stator core 12b in order to maximize the spot ratio as shown in FIG. 3. 12c) is fabricated in the shape of "memory" and "back memory" and laminated radially symmetrically to each other.

The mover assembly 20 is a magnet frame 21 arranged to move between the outer stator 11 and the inner stator 12 and the magnet frame 21 to correspond to the winding coil C of the stator assembly 10. It consists of a plurality of magnets 22 fixed at equal intervals on the outer circumferential surface.

13, which is not described in the drawings, is a fixing ring.

The conventional reciprocating motor as described above operates as follows.

That is, when a current is applied to the winding coil C of the outer stator 11, a flux is formed around the winding coil C and flows to the inner stator 12 along one path of the outer stator 11. Is again formed a kind of 'closed loop (closed loop)' flowing to the other side path of the outer stator (11).

At this time, when the magnet 22 of the movable assembly 20 is placed on the flux formed by the winding coil C, the magnet 22 interacts with the flux of the winding coil C to wind the winding coil C. The magnet frame 21 reciprocated in a straight line while being pushed or pulled along the flux direction.

However, in the conventional reciprocating motor as described above, in order to reduce the iron loss caused by the alternating magnetic flux and to increase the magnetic path area through which the magnetic flux passes, the thin steel sheets 12a are radially laminated one by one or two thin steel plates 12b by two pairs. Although stacking 12c radially, this has a problem in that the lamination of thin steel sheets 12a, 12b, 12c is complicated and limited in automation, resulting in low productivity and excessive production cost. .

In addition, when the inner stator 12 is manufactured by laminating the thin steel sheets 12b and 12c, there is no space for passing the bolts between the thin steel sheets so that the inner stator 12 cannot be directly fixed between the two frames. As the inner stator 12 is fixed by the tightening force of (11), the fixing force to the inner stator 12 decreases by that amount, which may lower the reliability of the motor.

The present invention has been made in view of the problems of the conventional reciprocating motor as described above, to provide a stator structure of the reciprocating motor that can increase the productivity and reduce the production cost to facilitate the internal stator easy and automated. There is a purpose.                         

In addition, an object of the present invention is to provide a stator structure of a reciprocating motor capable of firmly fixing the outer stator as well as the inner stator between both frames.

In order to achieve the object of the present invention, the outer stator having a winding coil, the inner stator disposed with a predetermined gap inside the outer stator, and the magnet between the outer stator and the inner stator flux between the two stators In a reciprocating motor including a mover that linearly reciprocates by means of the inner stator, the inner stator includes a stator block made of a cylindrical shape by a powder metallurgy method using a soft magnetic composite, and a plurality of thin stator cores. It provides a stator structure of a reciprocating motor, characterized in that the radially laminated in a cylindrical shape consisting of a stator laminated body inserted into the outer peripheral surface or the inner peripheral surface of the stator block.

EMBODIMENT OF THE INVENTION Hereinafter, the stator structure of the reciprocating motor by this invention is demonstrated in detail based on one Example shown in an accompanying drawing.

Figure 4 is a perspective view showing the inner stator of the reciprocating motor of the present invention, Figure 5 is a side view showing the inner stator of the present invention, Figure 6 is a cross-sectional view fixing the inner stator of the present invention with the outer stator, Figure 7 is "I-I" is a cross-sectional view, Figure 8 is a cross-sectional view showing another embodiment of the present invention inner stator.

Referring to Figure 1, the stator assembly of the reciprocating motor of the present invention is the outer stator (11) formed in a cylindrical shape so as to be located on the outside of the movable assembly (20), and a constant inter-core distance inside the outer stator (11) It consists of an inner stator 100 formed in a cylindrical shape so as to leave.

The outer stator 11 forms a thin stator core in a "dimple" shape to form a lamination radially on the outer circumferential surface of the bobbin (unsigned) wound around the winding coil C, or "remembers" a thin stator core (unsigned). It is also possible to form a core block (unsigned) formed by stacking a plurality of sheets each by fabricating a "and a" reverse memory "shape and then laminating them in a symmetrical radial manner.

The inner stator 100 is a stator block 110 made of a soft magnetic compound (Soft Magnetic Composite) and a plurality of thin stator cores 121 are radially laminated in a cylindrical shape as shown in FIG. 4 to form the stator block 110. It consists of one stator laminate 120 coupled to.

The stator block 110 is a kind of powder metal, and is formed in a cylindrical shape by using powder metallurgy to improve soft magnetic powder coated with an insulating coating material to improve electrical magnetic properties for application to electromagnetic systems such as motors.

The stator stack 120 is formed by radially stacking a thin stator core 121 of a rectangular parallelepiped in a cylindrical shape when side projecting. The stator cores 121 are fixed by pressing the retaining ring 122 on both sides thereof. To combine.

In the drawings, the same reference numerals are given to the same parts as in the prior art.

The stator structure of the reciprocating motor of the present invention as described above has the following effects.

That is, when flux is formed between the outer stator 11 and the inner stator 100 by applying power to the winding coil C, the gap between the outer stator 11 and the inner stator 100 lies in the gap. The mover assembly 20 continuously reciprocates while moving along the direction of the flux.

Here, the inner stator 100 puts a plurality of stator cores 121 on the outer circumferential surface or the inner circumferential surface of the stator block 110 manufactured by the so-called powder metallurgy method, which is placed in a mold having a predetermined shape and heated to an appropriate temperature. By press-fitting and combining the stator laminated body 120 manufactured by laminating in a cylindrical shape, the inner stator 100 can be easily manufactured as compared with the cylindrical stator cores being radially laminated.

In addition, when the entire inner stator 100 is made of expensive soft soft powder, the material cost may be excessively increased, thereby increasing the manufacturing cost. However, as in the present invention, part of the inner stator 100, that is, the stator block, may be increased. By using only the soft magnetic powder (110) and the rest of the stator core (121) laminated relatively inexpensive stator core 120 can be used to reduce the production cost for the inner stator.

In addition, the magnetic path area of the inner stator 100 is widened to prevent magnetic saturation of the magnetic body, thereby improving the efficiency of the motor.

Meanwhile, in order to fix the outer stator 11 and the inner stator 100, the frames 210 and 220 are brought into close contact with both sides of the two stators 11 and 100, respectively, as shown in FIGS. 6 and 7. The outer stator 11 and the inner stator 100 are fixed while tightening the two frames 210 and 220 using the long fastening bolt 230 penetrating the inner stator 100.

To this end, a plurality of through-holes 111 are formed in the stator block 110 of the inner stator 100 in the axial direction such that the long fastening bolts 230 pass therethrough, and on one side of the frame 210 facing the same. A fastening groove 221 is formed in the bolt hole 211 and the other frame 220.

Here, when the outer stator 11 is stacked as described above, both frames 210 and 220 are fastened by fastening bolts 14 from the outer side of the outer stator 11, while fixing a plurality of thin sheets. When the stator cores 121 are stacked to form a core block (unsigned), and then radially stacked, the two frames 210 and 220 are tightened with fastening bolts 14 passing between the core blocks. By fixing the outer stator 11, the outer stator 11 can be more firmly fixed.

Meanwhile, in the above-described exemplary embodiment, the stator stack 120 is inserted into and coupled to the outer circumferential surface of the stator block 110, but the stator stack is formed on the inner circumferential surface of the stator block 210 as shown in FIG. 8. It may be combined by inserting (220). In this case as well, the stator block 210 is formed by a powder metallurgy using a soft metal powder and forms a through hole 211 for fastening the bolt in the axial direction, while the stator laminate 220 forms the stator core 221. After the radial lamination, it is preferable to maintain the mold by the fixing ring 222.

In the stator structure of the reciprocating motor according to the present invention, the stator block is formed by forming a stator block by the powder metallurgy method and pressing and fixing the stator laminated body in which several stator cores are stacked in a cylindrical shape. This greatly simplifies the assembly process and increases productivity while using less expensive powdered metals to prevent excessive increase in production cost.

Further, by arranging the frame on both sides of the inner stator and fastening to the frame by fastening bolts through the inner stator, the outer stator as well as the inner stator can be firmly fixed to increase the reliability of the motor.

Claims (4)

An outer stator having a winding coil, an inner stator arranged with a predetermined gap inside the outer stator, and a magnet between the outer stator and the inner stator to move reciprocally in a straight line by flux between the two stators In a reciprocating motor including a ruler, The inner stator is a cylindrical stator block manufactured by powder metallurgy using a soft magnetic composite, and a plurality of thin stator cores are radially laminated in a cylindrical shape to be inserted into the outer circumferential surface or the inner circumferential surface of the stator block. A stator structure of a reciprocating motor, comprising a stator laminated body. The method of claim 1, The stator laminated body is a stator structure of a reciprocating motor, characterized in that for coupling the respective stator core by pressing the fixing ring on both sides. The method of claim 1, Frames are disposed on both sides of the outer stator and the inner stator, respectively, and fastening both frames with long fastening bolts passing through the stator block of the inner stator to support the outer stator and the inner stator. Stator structure. The method of claim 3, The stator structure of the reciprocating motor, characterized in that the stator block is formed with a plurality of through holes so that the fastening bolt penetrates in the axial direction.

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