KR100480376B1 - Structure for fixing magnet in reciprocating compressor - Google Patents

Abstract

The present invention relates to a magnet fixing structure of a reciprocating compressor, and the present invention provides a mounting groove having a predetermined depth on the outer circumferential surface of the inner stator is inserted into the outer stator of the reciprocating motor for generating a linear reciprocating driving force to be linearly movable. And a magnet having a predetermined thickness and a predetermined area is inserted into and fixed to a mounting groove of the inner stator so as to be positioned between the outer stator and the inner stator to firmly connect the inner stator and the magnet constituting the reciprocating motor. When the piston that compresses the gas together with the inner stator and the magnet constituting the reciprocating motor receives the linear reciprocating driving force of the reciprocating motor, the vibration occurs during the process of compressing the gas during linear reciprocating motion or when it operates for a long time. on So that the magnets would have to drive safely, without departing.

Description

Magnet fixed structure of reciprocating compressor {STRUCTURE FOR FIXING MAGNET IN RECIPROCATING COMPRESSOR}

The present invention relates to a reciprocating compressor, and in particular, to constitute a reciprocating motor for generating a linear reciprocating driving force, and is fixed to the inner stator and the inner stator coupled to the piston for compressing the gas and linear reciprocating motion with the piston The present invention relates to a magnet fixing structure of a reciprocating compressor capable of solidifying a coupling state of a magnet.

Generally, a compressor is a device that compresses a gas such as a refrigerant. There are various kinds of such compressors, such as a rotary compressor, a reciprocating compressor, a scroll compressor, and the like, according to a method of compressing a gas.

1 illustrates an example of a reciprocating compressor currently being researched and developed. As shown in the drawing, the reciprocating compressor includes a container 100 having a suction pipe 10 through which gas is sucked, and a through hole 210. The formed cylinder portion 220 is provided in the axial direction inside the front frame 200 and the outer stator 310 fixedly coupled to one side of the front frame 200 is mounted inside the container 100. A reciprocating motor 300 having a magnet 330 coupled to the inner stator 320 so that the inner stator 320 is movably inserted therebetween and positioned between the inner stator 320 and the outer stator 310; The inner stay is inserted into the cylinder through-hole 210 of the front frame 200 and coupled with the inner stator 310 of the reciprocating motor to receive a linear reciprocating driving force of the reciprocating motor 300. A piston 400 linearly reciprocating together with the rotor 310 and the magnet 330, and a rear frame 500 which covers the piston 400 and fixes and supports the outer stator 310 of the reciprocating motor. And, the resonant spring unit 600 for elastically supporting the movement of the piston 400 and the inner stator 310 and the magnet 330, and to inhale and discharge the gas in accordance with the linear reciprocating motion of the piston 400 It is configured to include a valve unit 700.

The resonant spring unit 600 is formed in a predetermined shape and the first spring supporter 610 is fixedly coupled to one side of the inner stator 350 and the piston 400 to be located on the front frame 200 side, and A second spring supporter 620 fixedly coupled to the other side of the inner stator 350 to be located at the rear frame 500 side, and a first spring positioned between the first spring supporter 610 and the front frame 200. It comprises a spring 630 and a second spring 640 located between the second spring supporter 620 and the rear frame 500.

The valve unit 700 is fixedly coupled to the end surface of the piston 400 to open and close the gas flow path F of the piston 400 and the cylinder through-hole of the front frame 200 ( A discharge cover 720 covering the 210, a discharge valve 730 positioned inside the discharge cover 720 to open and close the through hole 210 of the front frame, and an interior of the discharge cover 720. It is positioned to include a valve spring 740 for elastically supporting the discharge valve 730. A discharge tube 20 through which gas is discharged is coupled to one side of the discharge valve 730.

Reference numeral 20 is a discharge tube, 340 is a winding coil, 800 is an oil supply means, F is a gas suction flow path, and P is a compression space.

Operation of the reciprocating compressor as described above is as follows.

First, when power is applied to the compressor, current flows through the winding coil 340 of the reciprocating motor, and flux is formed in the outer stator 310 and the inner stator 320, and the outer stator 310 and the inner stator 320 are formed. The inner stator 320 and the magnet 330 generate a linear reciprocating driving force by the interaction between the flux formed in the cross-section) and the flux by the magnet 330.

The linear reciprocating driving force of the inner stator 320 and the magnet 330 is transmitted to the piston 400, and as shown in FIG. 2, the piston 400 together with the inner stator 320 and the magnet 330. ) Is linearly reciprocated in the cylinder through-hole 210 of the front frame 200 and the valve unit as the piston 400 linearly reciprocates in the cylinder through-hole 210 of the front frame 200. The refrigerant suctioned into the suction pipe 10 together with the operation of the 700 is sucked into the compression space P and compressed, and the high temperature and high pressure refrigerant compressed in the compression space P is discharged with the discharge cover 720. Out of the container 100 through the tube 20, it is repeated such a process.

The resonant spring unit 600 stores and discharges the linear reciprocating driving force of the reciprocating motor 300 as elastic energy and induces the resonance motion of the piston 400, the inner stator 320, and the magnet 330. Let's go.

On the other hand, the fixed structure of the magnet 330 fixed to the inner stator 310 and the inner stator 310 constituting the reciprocating motor 300 and connected to the piston 400 and reciprocating together are As follows. First, the inner stator 320 is formed in a cylindrical shape so as to be inserted at a predetermined interval inside the outer stator 310, and the magnet 330 is formed to have a predetermined thickness and area so that the magnet 330 is inner. The outer peripheral surface of the stator 320 is fixed by being bonded by an adhesive at a predetermined interval.

However, in the conventional structure as described above, since the magnet 330 is bonded and fixedly bonded to the outer circumferential surface of the inner stator 320 by the adhesive, the inner stator 320 and the magnet 330 resonate with the piston 400. When the vibration is generated in the process of linear reciprocating motion in the axial direction while being elastically supported by the spring unit 600, or if the drive for a long time there is a risk that the magnet 330 is separated from the inner stator 320 will cause damage .

An object of the present invention devised in view of the above-described points is that an inner stator and inner which are coupled to a piston for compressing gas and linearly reciprocate with the piston constitute a reciprocating motor that generates a linear reciprocating driving force. The present invention provides a magnet fixing structure of a reciprocating compressor that can firmly fix a magnet fixedly coupled to a stator.

In order to achieve the object of the present invention as described above, a mounting groove having a predetermined depth is formed on the outer circumferential surface of the inner stator to be linearly moved inside the outer stator of the reciprocating motor generating a linear reciprocating driving force, A magnet fixing structure of a reciprocating compressor is provided, wherein a magnet having a predetermined area is inserted into and fixed to a mounting groove of the inner stator so as to be positioned between the outer stator and the inner stator.

In addition, an inner stator is inserted into the outer stator of the reciprocating motor generating a linear reciprocating driving force, and the magnet is in contact with the outer circumferential surface of the inner stator so as to be located between the outer stator and the inner stator. A magnet fixing structure of a reciprocating compressor is provided, wherein a magnet fixing member having a shape is fixedly coupled to the inner stator and fixedly supports the magnet.

Hereinafter, the reciprocating compressor magnet fixing structure of the present invention will be described according to the embodiment shown in the accompanying drawings.

Figure 3 shows a reciprocating compressor equipped with an embodiment of the reciprocating compressor inner stator fixing structure of the present invention, as shown in the first, the reciprocating compressor is a container 100 provided with a suction pipe (10) And a cylinder portion 220 having a through hole 210 formed therein, the front frame 200 mounted inside the container 100 and an outer stator 310 fixedly coupled to one side of the front frame 200. The inner stator 350 is inserted into the inner stator 350 so as to be movable in the axial direction, and the magnet 360 is coupled to the inner stator 350 so as to be positioned between the inner stator 350 and the outer stator 310. A linear reciprocating tool of the reciprocating motor 300 is inserted into the synchronous motor 300 and the cylinder through-hole 210 of the front frame 200 and coupled to the inner stator 310 of the reciprocating motor. The piston 400 linearly reciprocates together with the inner stator 310 and the magnet 360 by receiving a force, and the piston 400 is opened, and the outer stator 310 of the reciprocating motor is fixedly supported. The rear frame 500, the resonant spring unit 600 elastically supporting the movement of the piston 400, the inner stator 310 and the magnet 360, and the linear reciprocating motion of the piston 400. And a valve unit 700 that sucks and discharges gas.

The outer stator 310 of the reciprocating motor has a through hole 312 formed in the cylindrical body 311 having a predetermined length and has a predetermined width and depth in the inner circumferential surface of the through hole 312 of the cylindrical body. An opening groove 313 having a shape is formed and the winding coil 340 is coupled to the opening groove 313.

The inner stator 350 is formed of a cylindrical body 351 longer than the length of the outer stator 310 and inserted into the cylindrical through hole 312 of the outer stator 310 at a predetermined interval and the inner stator. The piston 400 is coupled to the inside of the cylindrical body 351. That is, the inner peripheral surface of the cylindrical body 311 of the outer stator and the outer peripheral surface of the cylindrical body 351 of the inner stator maintain a constant distance.

The magnet 360 is fixedly coupled to the inner stator 350 such that the magnet 360 is positioned between the outer stator 310 and the inner stator 350. The magnet 360 is composed of a plurality of arranged on the outer circumferential surface of the inner stator 350 at regular intervals in the circumferential direction.

The magnet 360 is fixedly coupled to the inner stator 350 has a mounting groove 352 having a predetermined depth on the outer circumferential surface of the inner stator cylindrical body 351 is formed, the cylindrical mounting groove 352 of the inner stator The magnet 360 is inserted into and fixed). The magnet 360 is formed to have a predetermined thickness and area, but is formed in a curved plate shape having a curvature corresponding to the curvature of the outer circumferential surface of the inner stator 350, and the mounting groove 352 of the inner stator is the magnet 360. It is formed to have a shape and a predetermined depth corresponding to the shape of the) and the magnet 360 may be press-fitted into the mounting groove 352 and fixedly coupled, and may be adhesively fixed by an adhesive.

Then, as shown in Figure 4, the magnet 360 is wrapped in the carbon fiber (C) to the inner stator 350, including the magnet 360 in the state of being inserted into the mounting groove (352) The carbon fiber C can be hardened and fixed.

In another modification of the mounting groove 352, the mounting groove 352 has an annular band in the circumferential direction to have a length and a predetermined depth corresponding to the length of the magnet 360 on the outer circumferential surface of the inner stator 350. It is formed in a shape and the magnet 360 is inserted and fixed to a predetermined interval in the mounting groove 352.

In another first embodiment for fixedly coupling the magnet 360 to the inner stator 350, as shown in FIG. 5, the magnet 360 is inserted and fixed to an outer circumferential surface of the cylindrical body 351 of the inner stator. The mounting groove 352 is formed, and the mounting groove 352 is formed by the protrusions 353 formed on the outer circumferential surface of the inner stator cylindrical body 351 at intervals corresponding to the length of the magnet 360, respectively. The protrusion 353 is formed to protrude and extend on the outer circumferential surface of the cylindrical body 351 of the inner stator to have a predetermined thickness and height. The magnet 360 is formed to have a predetermined thickness and area, but is formed in a curved plate shape having a curvature corresponding to the curvature of the outer circumferential surface of the inner stator 350 and is formed by the protrusions 353 and 353. It is inserted into and fixed to the mounting groove 352.

In another second embodiment of fixedly coupling the magnet 360 to the inner stator 350, as shown in FIG. 6, the inner stator 310 is positioned between the outer stator 310 and the inner stator 350. The magnet 360 is positioned to be in contact with the outer circumferential surface of the 350, and the magnet fixing member 370 having the cross-sectional shape of the "needle" and "reverse teeth" is supported by the inner stator 350 so as to support both ends of the magnet 360. Fixed and coupled to the) is made by fixing the magnet 360.

The magnet 360 is formed to have a predetermined thickness and area, but is formed in a curved plate shape having a curvature corresponding to the curvature of the outer circumferential surface of the inner stator 350. In addition, the magnet fixing member 370 is in contact with the outer circumferential surface of the inner stator 350 and the end portion thereof is joined to the inner stator 350 by the horizontal contact portion 371 and the horizontal contact portion 371, followed by the magnet 360. It is formed to be bent extending to a length less than the height of the vertical portion 372 to support the side of the magnet 360 and the magnet fixing member 370 is located on both sides in the longitudinal direction of the magnet 360, respectively It is fixedly coupled to fix the magnet 360.

The magnet fixing member 370 is formed to have a length corresponding to the length in the horizontal direction of the magnet 360 is fixedly coupled to both sides of each magnet 360, or the magnet fixing member 370 is formed in an annular shape The magnets 360 arranged in the circumferential direction on the outer circumferential surface of the inner stator 350 may be fixedly coupled in a batch.

In another third embodiment of fixedly coupling the magnet 360 to the inner stator 350, as shown in FIG. 7, the inner stator 310 is positioned between the outer stator 310 and the inner stator 350. The magnet 360 is positioned to be in contact with the outer circumferential surface of the 350, and the magnet fixing member 370 having the "stepped" and "reverse staircase" cross-sectional shapes to support both ends of the magnet 360 includes the inner stator 350. Fixed and coupled to the) is made by fixing the magnet 360.

The magnet 360 is formed to have a predetermined thickness and area, but is formed in a curved plate shape having a curvature corresponding to the curvature of the outer circumferential surface of the inner stator 350. In addition, the magnet fixing member 370 is in contact with the outer circumferential surface of the inner stator 350 and the end portion thereof is joined to the inner stator 350 by the horizontal contact portion 371 and the horizontal contact portion 371, followed by the magnet 360. Is formed to be bent and extended to a length corresponding to the height of the vertical portion 372 supporting the side surface of the magnet 360 and is formed to be bent and extended to a predetermined length following the vertical portion 372 to the upper surface of the magnet 360 It consists of a horizontal fixing part 373 supporting the magnet fixing member 370 is fixedly coupled to be located on both sides in the longitudinal direction of the magnet 360 to fix the magnet 360.

The magnet fixing member 370 is formed to have a length corresponding to the length in the horizontal direction of the magnet 360 is fixedly coupled to both sides of each magnet 360, or the magnet fixing member 370 is formed in an annular shape The magnets 360 arranged in the circumferential direction on the outer circumferential surface of the inner stator 350 may be fixedly coupled in a batch.

As a modification of the third embodiment, as shown in FIG. 8, the thickness of the horizontal fixing portion 373 of the magnet fixing member is formed on the upper surface of the magnet 360 positioned to be in contact with the outer circumferential surface of the inner stator 350. Corresponding stepped grooves 361 are formed, and the horizontal fixing part 373 is inserted into the stepped grooves 361 of the magnet, respectively, to fix the magnets 360. In this case, the upper surface of the magnet 360 and the upper surface of the horizontal fixing part 373 form the same surface.

In another modification of the third embodiment, as shown in FIG. 9, both longitudinal side surfaces of the magnet 360 positioned to contact the outer circumferential surface of the inner stator 350 are formed to be inclined. In addition, the magnet fixing member 370 is formed to have a predetermined thickness and length to be in contact with the outer circumferential surface of the inner stator 350, and a horizontal contact portion 371 and an end thereof joined to the inner stator 350 and the horizontal contact portion ( 371 is formed to be inclined at an angle corresponding to the side inclined surface 362 of the magnet 360 is formed of an inclined fixing portion 374 for supporting the inclined surface 362 of the magnet. The magnet fixing member 370 is fixedly coupled to the outer circumferential surface of the inner stator 350 so as to be located at both sides of the magnet 360 in the longitudinal direction, respectively, to fix the magnet 360.

The magnet fixing member 370 is preferably bonded to the outer peripheral surface of the inner stator 350 by welding.

In another fourth embodiment of fixedly coupling the magnet 360 to the inner stator 350, as shown in FIG. 10, a plurality of magnets 360 are circumferentially formed on the outer circumferential surface of the cylindrical body 351 of the inner stator. Is arranged. The magnet fixing member 370 is formed to surround the outer circumferential surface of the inner stator 350 including the magnets 360 so as to fix the magnets 360. The magnet fixing member 370 wraps the outer circumferential surface of the inner inner stator 350 including the magnets 360 with carbon fibers and then hardens the carbon fibers.

On the other hand, the outer stator 310 and the inner stator 350 is preferably made of a laminate laminated radially so that a plurality of thin plates each having a predetermined shape to form a cylindrical shape.

20 is a discharge tube, 340 is a winding coil, 610 is a first spring supporter, 620 is a second spring supporter, 630 is a first spring, 640 is a second spring, and 710 is a suction valve , 720 is a discharge cover, 730 is a discharge valve, 740 is a valve spring, 800 is an oil supply means, F is a gas suction flow path, and P is a compression space.

Effects of the reciprocating compressor magnet fixing structure of the present invention as described above are as follows.

First, the operation of the reciprocating compressor is performed by applying an alternating current to the reciprocating motor 300, and the flux formed by the outer stator 310 and the inner stator 350 and the flux formed by the magnet 360. By the interaction of the magnet 360 and the inner stator 350 fixedly coupled to the magnet 360 is a linear reciprocating motion and the linear reciprocating motion of the inner stator 350 and the magnet 360 is the piston 400 The piston 400 is linearly reciprocated in the cylindrical through-hole 210 of the front frame, that is, the compression space P. While the piston 400 linearly reciprocates in the through-hole 210 of the front frame cylinder, the valve unit 700 operates while gas is sucked into the compression space P of the front frame, compressed and discharged. The same process is repeated. At this time, the resonant spring unit 600 stores and discharges the linear reciprocating driving force of the reciprocating motor 300 as elastic energy, and also performs the resonant motion of the piston 400, the inner stator 350 and the magnet 360. It is triggered.

In the present invention, the magnet 360 coupled to the inner stator 350 is inserted into and fixed to the mounting groove 352 formed on the outer circumferential surface of the cylindrical body 351 of the inner stator, so that the coupling state of the magnet 360 is firm. In particular, it maintains a firm coupling against vibrations in the axial and circumferential directions. In addition, since the magnet 360 is inserted into and fixed to the mounting groove 352 of the inner stator, the air gap between the inner stator 350 and the outer stator 310 is reduced to increase the output of the motor.

In addition, when the magnet 360 is fixedly coupled to the inner stator 350 by the magnet fixing member 370, the magnet 360 is supported by the inner stator 350 by the magnet fixing member 370. Since it is fixed, the coupling state of the magnet 360 is firm, and in particular, the magnet 360 maintains a firm coupling state against vibration in the axial direction and the circumferential direction.

As described above, the magnet fixing structure of the reciprocating compressor according to the present invention is firmly coupled to the inner stator and the magnet constituting the reciprocating motor to receive the linear reciprocating driving force of the reciprocating motor to receive the reciprocating motor. Together with the inner stator and the magnet, the piston operates linearly and reciprocates while compressing the gas, even if vibration occurs or it operates for a long time, the magnet operates safely without being detached, thereby increasing the reliability of the compressor. have.

1 is a cross-sectional view of a reciprocating compressor currently under development,

2 is a cross-sectional view showing an operating state of the reciprocating compressor;

3 is a cross-sectional view of a reciprocating compressor equipped with an example of the reciprocating compressor magnet fixing structure of the present invention;

4, 5, 6, 7, 8, 9 and 10 are cross-sectional views showing another embodiment of the reciprocating compressor magnet fixing structure of the present invention, respectively.

** Explanation of symbols for main parts of drawings **

300; Reciprocating motors 310; Outer stator

350; Inner stator 352; Mounting groove

353; Spin 360; Magnet

361; Stepped groove 370; Magnet fixing member

371; Horizontal contacts 372; Vertical section

373; Horizontal fixing part 374; Fixed slope

Claims (8)

A mounting groove having a predetermined depth is formed in the outer circumferential surface of the inner stator to be linearly moved in the outer stator of the reciprocating motor generating a linear reciprocating driving force, and a magnet having a predetermined thickness and a predetermined area is formed in the outer stator and the inner. Magnet fixed structure of the reciprocating compressor, characterized in that the insertion groove is fixed to the mounting groove of the inner stator to be located between the stator. The magnet fixing structure of the reciprocating compressor according to claim 1, wherein the mounting groove of the inner stator is formed by a projection projecting at a predetermined height on an outer circumferential surface of the inner stator. The inner stator is inserted into the outer stator of the reciprocating motor that generates the linear reciprocating driving force, and the magnet is in contact with the outer circumferential surface of the inner stator so as to be located between the outer stator and the inner stator. A magnet fixing structure for a reciprocating compressor, characterized in that the magnet is fixed to the inner stator by a magnet fixing member that supports both front and rear ends and is fixedly coupled to the inner stator. The magnet fixing member of claim 3, wherein the magnet fixing member is formed to have a predetermined thickness and length to be in contact with the outer circumferential surface of the inner stator, and the end of which is smaller than the height of the magnet following the horizontal contact portion and the horizontal contact portion joined to the inner stator. The magnet fixing structure of the reciprocating compressor, characterized in that it is formed extending bent to a length to support the side of the magnet, respectively located on both sides in the longitudinal direction of the magnet. The magnet fixing member of claim 3, wherein the magnet fixing member is formed to have a predetermined thickness and length to be in contact with the outer circumferential surface of the inner stator, and the end portion thereof corresponds to a horizontal contact portion joined to the inner stator and a height of the magnet following the horizontal contact portion. It is formed to be extended to the length of the vertical portion to support the side of the magnet and the vertical portion is formed to be extended to be bent to a predetermined length to support the upper surface of the magnet is located on both sides in the longitudinal direction of the magnet Magnet fixed structure of the reciprocating compressor, characterized in that. The method of claim 5, wherein the stepped groove corresponding to the thickness of the horizontal fixing portion is formed on the upper surface of the magnet which is in contact with the outer peripheral surface of the inner stator, characterized in that the horizontal fixing portion is located in the stepping groove of the magnet, respectively Magnet fixed structure of reciprocating compressor. According to claim 3, wherein the longitudinal both sides of the magnet positioned in contact with the outer circumferential surface of the inner stator is formed to be inclined, the magnet fixing member is formed to have a predetermined thickness and length to contact the outer circumferential surface of the inner stator and the end A horizontal contact portion joined to the inner stator and an inclined fixing portion extending from the horizontal contact portion to be inclined at an angle corresponding to the side inclined surface of the magnet to support the inclined surface of the magnet, respectively positioned on both sides in the longitudinal direction of the magnet; Magnet fixed structure of the reciprocating compressor, characterized in that. The magnet of the reciprocating compressor according to claim 1 or 3, wherein the magnet is secured by carbon fiber wrapping an outer circumferential surface of an inner stator including the magnet and then curing the carbon fiber wrapped around the magnet. Fixed structure.