KR20070029021A - Linear motor and compressor having the linear motor - Google Patents

Abstract

A linear motor and a compressor having the same are provided to obtain a high capacity by installing an electromagnet inside/outside of a permanent magnet. A linear motor includes a movable element, a stator, and an elastic unit(30). The movable element has a permanent magnet(27) having different poles along a shaking direction. The stator has a fixing iron core, and a plurality of electromagnet(23,26) which wind a coil to the fixing iron core. The elastic unit(30) supports the movable element to be vibrated along the shaking direction of the movable element. When the plurality of electromagnets of the stator is excited by an AC current, each magnetic polarity is arranged to apply an alternative force to the permanent magnet(27) by the magnetic poles, attraction, repulsion.

Description

LINEAR MOTOR AND COMPRESSOR HAVING THE LINEAR MOTOR}

1 is a schematic diagram of a first embodiment of a linear motor compressor according to the present invention;

2 is a sectional view of a second embodiment of a linear motor compressor according to the present invention;

3 is a sectional view of a third embodiment of a linear motor compressor according to the present invention;

4 is a view for explaining a fourth embodiment of the linear motor compressor according to the present invention, (a) is a schematic diagram, (b) is A-A 'cross-sectional view.

5 is a perspective view of a permanent magnet used in the linear motor compressor of the embodiment shown in FIGS.

6 is an explanatory view of the operating principle of the embodiment shown in FIG.

FIG. 7 is a view for explaining a coil winding direction of each electromagnet in the embodiment shown in FIG.

8 is an explanatory view of the operating principle of the embodiment shown in FIG.

9 is a schematic cross-sectional view of a conventional linear motor compressor.

10 (a) and (b) are perspective views of a permanent magnet used in the conventional linear motor compressor shown in FIG.

11 is an explanatory view of the operating principle of the conventional linear motor compressor shown in FIG.

<Brief Description of Drawings>

11 cylinder 12 piston

13 Cylinder head 14 Exhaust valve

15 Intake valve 23 First electromagnet

26 Second Electromagnet 27 Permanent Magnet

30 resonant spring 40 gap

50 Cylinder housing 60 Housing cover

The present invention relates to a linear motor and a linear motor compressor, and more particularly, a linear motor having a permanent magnet formed with magnetic poles having different polarities in a direction in which the piston moves, and which can be manufactured with increased output and compactly. A compressor using a linear motor.

In addition, the linear motor and the linear motor having a cylindrical permanent magnet to install an electromagnet not only in the exterior of the permanent magnet, but also to the inside, so that the increased thrust by the internal and external electromagnets to act to facilitate the implementation of a large-capacity compressor It relates to a compressor having a.

U.S. Pat.Nos. 6250,895 and 6,413,057 or PCT International Application Publication No. WO 02/086321 A1 disclose a technique for a linear motor compressor for compressing a working fluid such as a refrigerator or an air conditioner. Fig. 9 schematically shows a common configuration of a conventional linear motor compressor disclosed in such a document. As shown in FIG. 9, the conventional linear motor compressor 100 uses a compressor 110 having a piston 102 reciprocating to compress a working fluid, and a power for reciprocating the piston 102. It includes a linear motor 120 for supplying, and a resonant spring 130 for supporting the piston 102 to reciprocate. The compressor 100 includes a cylinder 101, a piston 102 inserted in one side of the cylinder 101 so as to be reciprocated, and fixed to the other side of the cylinder 101, and a space and a piston inside the cylinder 101. The cylinder head 104 which forms the compression space CV between 102 is provided. In addition, the suction valve 105 installed in the piston 102 so that the working fluid is sucked into the compression chamber when the piston 102 is reversed, and the cylinder head installed so that the compressed working fluid is discharged in the compression chamber when the piston 102 is advanced. And a discharge valve 104 installed at 103. Of course, like the embodiment shown in the PCT publication, both the discharge valve 104 and the suction valve 105 may be installed in the cylinder head 103. The linear motor 120 includes a cylindrical inner core 123 provided around the cylinder 101, an outer core 122 provided to form a constant gap 140 with the outside of the inner core 123, and an outer The coil 121 is wound inside the core 122. In addition, the permanent magnet 124 of the cylindrical shape provided in the gap 140, and a permanent magnet support member 125 for connecting and fixing the permanent magnet 124 to the piston (102). The outer core 122 and the inner core 123 are formed by stacking a plurality of ferromagnetic plates, and the slot 122c in the circumferential direction so that different magnetic poles 122a and 122b are formed on the inner surface of the outer core 122. Is formed. In addition, the cylindrical permanent magnet 124 is formed so that the outer peripheral side 124a and the inner peripheral side 124b of the cylinder have different magnetic poles, as shown in FIG. 10 (a) or FIG. 10 (b). have.

FIG. 11 shows the operation principle when AC power is supplied to the conventional linear motor compressor 100 as described above. When AC power is supplied to the coil 121, the magnetic poles 122a and 122b of the inner circumferential surface of the outer yoke 122 alternately change. That is, when the N pole is induced in one of the poles 122a, the S pole is induced in the other pole 122b. Accordingly, each of the magnetic poles 122a and 122b alternately exerts an attractive force and a repulsive force on the permanent magnet 124 having the S pole formed on the outer circumferential surface, thereby acting on the thrust alternately with the permanent magnet. As shown in FIG. 11, the half-cycle of the supplied AC power is in the left arrow direction (sections 11A, 11B, and 11C) and in the remaining half-cycle (sections 11C, 11D, and 11A) in the direction of the right arrow. Thrust is applied to the permanent magnet. Accordingly, the piston 102 connected to the permanent magnet 124 reciprocates in the piston 101 at the same frequency as the supplied AC power. At this time, the thrust applied to the permanent magnet is proportional to the intensity of the current flowing through the coil 121 and the magnetic flux density of the permanent magnet 124.

However, the conventional linear motor compressor as described above uses a permanent magnet having a cylindrical shape as shown in FIG. 10 (a), and in particular, different magnetic poles are provided on the outer circumferential side 124a and the inner circumferential side 124b of the permanent magnet. Since the formed permanent magnet is used, an inner core is necessarily required to form a path to the magnetic pole on the inner circumferential side. Therefore, a space for installing the inner core in the linear motor compressor is required, and the size of the compressor is increased by the space. Even if the permanent magnet of the type shown in Fig. 10 (b) is used, the inner core is required because the inner and outer circumferences have different magnetic poles.

In addition, the permanent magnet having a distribution of magnetic poles as shown in Fig. 10 (a) is a magnetic pole formed on the outer peripheral surface of the cylinder and the volume of the magnetic pole formed on the inner circumferential surface of the cylinder with ordinary permanent magnet materials (ferrite, NdFeB, Bonded, etc.). It is practically difficult to manufacture the same volume of. Due to the volume imbalance as described above, the magnetization cannot be magnetized to have the maximum magnetic force in the manufacture of the permanent magnet, and the coercive force becomes smaller than other permanent magnets of the same size, and the magnetic force decreases rapidly over time. There is a problem. The permanent magnet of the type shown in FIG. 10 (b) is also difficult to form the same volume magnetized to the north pole and the south pole, and the manufacturing process is also complicated and the coercive force cannot be increased. Accordingly, there is a problem in that the thrust acting on the piston cannot be increased as compared to other permanent magnets, and thus a large capacity compressor cannot be manufactured. In addition, when the size of the permanent magnet is increased in order to increase the output when used in a device using a home power supply, the distance between the auxiliary core (inner core) and the winding main winding (outer core) is increased, rather, It significantly lowers the electromagnetic force of the auxiliary core induced by the main core, rather it interferes with the movement of the permanent magnet.

Since the conventional linear motor compressor has the above problems, commercial products for mass production having an output of 150 Watt or more have not been developed.

The present invention is to solve the problems of the conventional linear motor compressor as described above. An object of the present invention is to change the shape of the permanent magnet to provide a linear motor that can be manufactured compact without the need for an auxiliary core. In addition, an object of the present invention is to provide a linear motor with increased output power to maximize the magnetizing force of the permanent magnet. In particular, it is an object of the present invention to provide a linear motor having a power of 1,200 Watt or more that is commercially available for mass production.

Another object of the present invention is to provide a compressor using a linear motor having the above object.

The linear motor of the present invention for achieving the above object, a plurality of movable members having a permanent magnet formed with different magnetic poles along the swing direction, a fixed iron core and a plurality of coils wound around the fixed iron core core And a stator having an electromagnet, and an elastic member for supporting the mover so as to be able to swing along the swinging direction of the mover. When the plurality of electromagnets of the stator are excited by an alternating current, their magnetic pole polarities are different. It is characterized in that it is arranged along the rotational direction to apply the alternating thrust to the permanent magnet by the magnetic force and attraction and repulsive force of the permanent magnet.

The permanent magnet has a cylindrical shape, and the plurality of electromagnets accommodate any one magnetic pole of the permanent magnet in the hollow, and a pair of hollow inner circumferential surfaces spaced at regular intervals from the outer circumferential surface of the accommodated permanent magnet. A first electromagnet having a first core having a slot formed in a circumferential direction and laminated with a ferromagnetic plate so as to form a magnetic pole, a first coil wound around the first core, and the other magnetic pole of the permanent magnet. A second core stacked in a circumferential direction and stacked in a circumferential direction such that a pair of magnetic poles is formed in the hollow and the hollow inner circumferential surface spaced at regular intervals from the outer circumferential surface of the accommodated permanent magnet; And a second electromagnet having a second coil wound in a direction opposite to the first coil in the core.

In addition, the third and fourth electromagnets are provided inside the cylindrical permanent magnet to operate together with the first and second electromagnets, thereby increasing the thrust applied to the permanent magnet. At this time, the electromagnets facing each other with respect to the permanent magnet, for example, the first and third electromagnets and the second and fourth electromagnets are facing each other with respect to the permanent magnet, and the electromagnets facing each other are in the direction of the generated magnetic flux. It should be wound so as to be the same, and in particular, it is preferable that the slot in which the magnetic pole of the electromagnet is formed is located in the same plane perpendicular to the swing direction.

In addition, the length of the core of each of the first to fourth electromagnet is preferably equal to the length of the permanent magnet.

On the other hand, the compressor using the linear motor of the present invention as described above is a cylinder, a piston inserted into one side of the cylinder is installed to enable reciprocating movement, and is fixed to the other side of the cylinder to the compression chamber between the cylinder and the piston A compressor including a cylinder head to be formed, an intake valve installed to suck the working fluid into the compression chamber when the piston is retracted, and an exhaust valve installed to discharge the compressed working fluid in the compression chamber when the piston is moved forward, and the piston A stator having a permanent magnet which is fixed to and formed with a permanent magnet having different magnetic poles formed along the swinging direction of the piston, a fixed iron core, and a plurality of electromagnets formed by winding a coil around the fixed core core; An elastic member for supporting the movable member in a swingable manner along the swinging direction of the movable member; In contrast, when the plurality of electromagnets of the stator are excited by an alternating current, the magnetic poles of the stator are arranged along the rotational direction such that the magnetic poles of the magnetic poles exert alternating thrust on the permanent magnets by the magnetic poles and the attractive force and the repulsive force of the permanent magnets. It features.

According to the present invention, a permanent magnet is connected and fixed to the piston so as to reciprocate with the piston and has a different magnetic pole along the reciprocating direction of the piston, and a plurality of electromagnets apply alternating thrust to the permanent magnet. It is. Therefore, since a separate auxiliary core is not required, a compact compressor can be provided.

In addition, since the plurality of electromagnets to apply alternating thrust in and out of the cylindrical permanent magnet, it is easy to manufacture a large-capacity compressor.

In addition, since the linear motor compressor according to the present invention has magnetic poles having different permanent magnets formed in the longitudinal direction, the linear magnetic compressor can be manufactured to have substantially the same volume of different magnetic poles, so that a permanent magnet having a large coercivity can be manufactured. The output of the compressor can be increased.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

1 shows a schematic diagram of a first embodiment of a linear motor compressor according to the invention. The linear motor compressor of the present embodiment has a compressor (C) fixed to the frame (F) and a linear motor (L) for providing the piston (2) with alternating thrust to reciprocate the piston (2) of the compressor (C). ) And a resonant spring (6) having one end connected to the piston (2) and the other end fixed to the frame (F) to support the reciprocating motion of the piston (2).

The piston 2 of the compressor C is inserted to one side of the cylinder 1 fixed to the frame F, and is installed to enable reciprocating motion. The cylinder head 3 is fixed to the other side of the cylinder 1, and the cylinder head 3 forms a compression chamber CV between the inside of the cylinder and the piston 2. In addition, an intake hole 3a and an exhaust hole 3b are formed in the cylinder head 3, and an intake valve 4 and an exhaust valve 5 are provided in each hole. Although not shown in detail, the intake valve 4 is opened when the piston moves backwards and the pressure inside the compression chamber CV becomes a predetermined value or less, and is closed when the piston moves forward. In addition, the exhaust valve 5 is closed when the piston 2 is reversed, and is opened when the piston 2 is moved forward and the pressure inside the compression chamber CV is equal to or higher than a predetermined value, and the compressed working fluid is discharged. It is supposed to be.

The linear motor L is supported by the permanent magnet support 7b and fixed to the piston 2 so as to be spaced apart from the magnetic pole 7a of the permanent magnet 7 by a predetermined distance. And a pair of electromagnets 8 and 9 fixed to it. The permanent magnet support 7b is made of a nonmagnetic material such as aluminum, and as shown in the figure, the permanent magnet support 7b surrounds the remaining portion except for the magnetic pole 7a of the permanent magnet and is fixed to the piston 2. In the present embodiment, the permanent magnet 7 has a plate shape, and magnetic poles 7a having different polarities N and S are arranged along the reciprocating direction (arrow direction) of the piston 7. In the pair of electromagnets 8 and 9, coils 8a and 9a are respectively wound in the same direction on a core formed by stacking ferromagnetic metal plates. Therefore, when AC power is supplied to each electromagnet, the magnetic poles 8a, 9a of each electromagnet disposed in parallel with the magnetic pole 7a of the permanent magnet 7 alternately have the same magnetic frequency as the AC power and exhibit the same magnetic properties. do. In addition, each of the electromagnets 8 and 9 is arranged so as to face at least part of different magnetic poles of the permanent magnet. Thus, when alternating currents of the same phase are provided to the respective electromagnets 8 and 9, the magnetic poles 8a and 9a of the respective electromagnets 8 and 9 are attracted to and repulsed by the magnetic poles 7a of the permanent magnet 7. Each acts to apply thrust alternately to the permanent magnet (7). For example, if the magnetic poles 8a and 9a of the electromagnets 8 and 9 are all the north poles, the permanent magnets 7 with the magnetic poles will be thrust in the right direction in the figure as shown, and if the poles are all the left poles, Thrust will be received in the direction. Therefore, the piston 2 connected to the permanent magnet 7 is reciprocated at the same frequency as the AC power source to compress the working fluid in the compression chamber CV. Further, in this embodiment, the length of the reciprocating direction of the piston 7 of each electromagnet 8, 9 is equal to the length of one magnetic pole of the electromagnet 7, and each electromagnet 8, 9 is permanent. The magnetic poles of the magnets 7 are spaced apart from one another in length. Therefore, the maximum stroke distance of the piston 2 is equal to the length of any magnetic pole of the permanent magnet 7.

2 shows a cross-sectional view of another embodiment of a linear motor compressor according to the invention. The linear motor compressor of this embodiment has a compressor 10 and a linear motor 20 for providing alternating thrust to the piston 12 to reciprocate the piston 12 of the compressor C, and the piston 12. Resonance spring 30 for supporting the reciprocating motion of the.

Compressor 10 is fixed to the cylinder 11, the piston 12 is inserted from one side of the cylinder 11 so that the reciprocating movement, and the other side of the cylinder 11 is fixed between the inside of the cylinder and the piston (2) And a cylinder head 13 forming a compression chamber CV. In addition, an exhaust hole 13a is formed in the cylinder head 13, and an exhaust valve 5 is provided in the exhaust hole 13a. The piston 12 is hollow and is provided with an intake hole 12a having a reduced diameter at the end of the side inserted into the cylinder, and an intake valve 15 is provided in the intake hole 12a. Although not shown in detail, the intake valve 15 is opened when the piston 12 moves backward and the pressure in the compression chamber CV becomes lower than a predetermined value so that the working fluid flows in. When the piston 12 moves forward, It is intended to be closed. In addition, the exhaust valve 14 is closed when the piston 12 is reversed, and when the piston 12 is moved forward and the pressure inside the compression chamber CV becomes a predetermined value or more, the compressed working fluid is discharged. It is supposed to be.

The linear motor L is inserted into the outer circumferential surface of the flange portion 28a of the permanent magnet support 28 and fixed to the cylindrical permanent magnet 27, and different magnetic poles disposed on the outer circumferential surface of the permanent magnet 27 ( 27a, 27b and a pair of electromagnets 23, 26 disposed with the cap 40 at regular intervals. The permanent magnet support 7b is made of a nonmagnetic material such as aluminum, and includes a fixing portion 28c for inserting and fixing the piston 12 and a radial extension from the fixing portion to support the resonant spring 30. It consists of a neck 28b and a flange 28a extending from the neck 28 in the longitudinal direction of the piston reciprocating motion so that the inner circumferential surface of the permanent magnet is tightly fixed. The permanent magnet 27 of this embodiment has a cylindrical shape as shown in Fig. 4, and is fixed to the permanent magnet support 7b so that the center axis coincides with the center axis in the reciprocating direction of the piston. In particular, since the permanent magnets 27 of the present embodiment have different magnetic poles 27a and 27b formed in the longitudinal direction, unlike the permanent magnets used in the conventional linear motor shown in FIG. Since it can be manufactured to be the same, permanent magnets having a large coercivity can be manufactured, thereby providing a linear motor compressor with a larger output.

The first electromagnet 23 and the second electromagnet 26 are cylindrical and are arranged adjacent to each other in the axial direction. The first electromagnet 23 has a hollow magnetic pole 27a of the permanent magnet 27. It accommodates inside, and the 2nd electromagnet accommodates the other one pole 27b inside. In addition, the first electromagnet 23 and the second electromagnet 26 are formed with a first core 22 and a second core having an inner circumferential surface spaced apart from the outer circumferential surface of the permanent magnet 27 accommodated at a predetermined interval 40, respectively. 25 and a first coil 21 and a second coil 24 wound around the first core 22 and the second core 25. In addition, the first core 22 and the second core 25 have slots 22c and 25c formed in the circumferential direction so that a pair of different magnetic pole surfaces are formed on the inner circumferential surface when current flows through the coil. The first core 22 and the second core 25 are formed by stacking ferromagnetic metal plates from which portions in which coils are wound and in which slots are formed are removed. In addition, the slots 22c and 25c formed in the respective cores 22 and 25 are formed in the center of the longitudinal direction of each core, and the lengths of the cores 22 and 25 of the respective electromagnets 23 and 26 are It has a length substantially the same as the length of the cylindrical permanent magnet (27). In addition, the elasticity of the resonant spring (31, 32) is adjusted so that the permanent magnet 27 is located slightly off the center of the pair of electromagnets (23, 26) in the stationary state. In the linear motor 20 of the present embodiment, as shown in FIG. 7, the permanent magnets 27 magnetized with different magnetic poles in the longitudinal direction are arranged along the reciprocating direction of the piston 12, and in opposite directions to each other. The first electromagnet 23 and the second electromagnet 26 having the coils wound thereon are adapted to apply thrust alternately to the permanent magnet 27. Therefore, unlike the conventional linear motor as shown in FIG. 6, a separate auxiliary core is not required, and thus the compressor can be manufactured compactly.

In addition, the linear motor compressor of the present embodiment is firmly fixed to the compressor 10 and the linear motor 20 by the cylinder housing 50 and the housing cover 60. The cylinder 11 and the cylinder head 13 are inserted into and fixed to the support holes 52 formed on one side of the cylinder housing 50. The cylinder housing 50 and the housing cover 60 have a disk shape, and the first electromagnet 23 and the second electromagnet 26 are inserted into and fixed between each other. The cylinder housing 50 and the cylinder cover 60 fixed in close contact with the cores 22 and 25 of the electromagnets 23 and 26 are made of non-magnetic aluminum. A through hole 62 is formed at the center of the housing cover 60 to allow the working fluid to pass through the hollow of the piston. In addition, one end of the first resonant spring is inserted into and supported by a spring support groove 51 formed in the cylinder housing 50, and the other end is supported by one neck portion 28b of the permanent magnet support 28. In addition, one end of the second resonance spring is inserted into and supported by the spring support groove 51 of the housing cover 60, and the other end is supported by the other neck 28b of the permanent magnet support 28.

In the present embodiment, the first coil 21 and the second coil 24 are wound in opposite directions as indicated by the current direction symbol in FIG. 2. Accordingly, when AC power of the same phase is supplied to each of the electromagnets 23 and 26, the first electromagnets disposed in parallel with the magnetic poles 27a and 27b of the permanent magnet 27 and the constant gap 40 interposed therebetween. The magnetic poles 22a and 22b of the 23 and the magnetic poles 25a and 25b of the second electromagnet 26 are respectively formed with alternating magnetic poles at the same frequency as the AC power source. When the magnetic poles 22a and 22b of the first electromagnet 23 are excited to the S-poles 22a and N-poles 22b in the order of AC power supplied in a certain phase, the magnetic poles 25a of the neighboring second electromagnets 26a. And 25b are reversely excited to the N pole 25b and the S pole 25a. Therefore, when an alternating current of the same phase is supplied to each of the electromagnets 23 and 26 in the stopped state, the magnetic poles 22b and 25a of the electromagnet facing the magnetic poles 27a and 27b of the permanent magnet 27 are both N. Since the pole, the magnetic force and the repulsive force is applied to the magnetic poles (27a, 27b) of the permanent magnet 27 to apply a thrust pushing the permanent magnet in one direction. When the permanent magnet 27 is moved in one direction by the thrust (assuming that it moves in the right direction in the figure), the magnetic pole 25a of the second electromagnet 26 adjacent to the direction in which the permanent magnet 27 moves is also a permanent magnet. Manpower will be added to (27). The piston 12 connected to the permanent magnet 27 is moved to the right by the applied thrust. At this time, the kinetic energy of the piston 12 is stored as elastic energy in the resonant spring 31. When the phase of the alternating current power is reversed, the polarities of the magnetic poles 22a, 22b, 25a, and 25b of the respective electromagnets 23 and 26 are also reversed, and the permanent magnet 27 is opposite to the moving direction of the permanent magnet 27. Thrust acts on the piston 12 to move it to the left. Therefore, when AC power is continuously applied to each of the electromagnets 23 and 26, the polarity of the magnetic pole of each of the electromagnets 23 and 26 is changed to the same frequency as that of the AC power, and is applied to the permanent magnet 27. Losing thrust is also alternating with the same frequency as the AC power source. Therefore, the piston 12 connected to the permanent magnet 27 is reciprocated at the same frequency as the AC power source to compress the working fluid sucked through the intake valve 15 into the compression chamber CV to exhaust valve 14. It is discharged to the outside through.

3 shows a cross-sectional view of another embodiment of a linear motor compressor according to the invention. The compressor of the embodiment shown in FIG. 3 differs from the compressor of the embodiment shown in FIG. 2 in one piece in four parts to facilitate the manufacture of the first core and the second core and to reduce the cost. That is, a pair of electromagnet cores are formed of a pair of outer cores 72 and 74, a central core 73, and a cover core 71 having a symmetrical structure. Since the rest of the configuration and operation and effect is the same as the linear motor compressor of the embodiment shown in FIG.

FIG. 6 is an explanatory diagram of an operating state according to a phase change of an AC power source applied to the linear motor compressors illustrated in FIGS. 2 and 3. When the AC power is supplied to a pair of electromagnets which are wound in opposite directions and arranged adjacently, the magnetic poles of each electromagnet are alternately changed in polarity. As shown, the magnetic poles are in turn the S-pole 22a-N-pole 22b-N-pole 25b-S-pole 22a or the N-pole 22a-S-pole 22b-S-pole 25b. It alternately changes to) -N pole 22a. In the case where the magnetic poles are arranged as S poles 22a-N poles 22b-N poles 25b-S poles 22a (sections 5A, 5B and 5C), the electromagnet in the direction of the arrow pointing left in the figure is shown. Thrust is applied to this permanent magnet 27, and the magnetic poles are arranged in the N pole 22a-S pole 22b-S pole 25b-N pole 22a (FIGS. 6C, 6D, and 6A). Section), the electromagnet exerts thrust on the permanent magnet 27 in the direction of the arrow pointing to the right in the figure. When the polarity of the AC power is switched, the magnetic pole of the electromagnet loses its magnetic force and does not provide thrust to the permanent magnet 27, but the elastic energy stored in the resonant spring acts as a restoring force to restore the permanent magnet to its original position. Therefore, the frequency of the left and right reciprocating motion of the permanent magnet 52 is synchronized with the frequency of the AC power supply, and one cycle of the power supply is equal to one reciprocation of the piston. That is, the piston 102 connected to the permanent magnet 124 reciprocates in the piston 101 at the same frequency as the supplied AC power. Therefore, the working fluid supplied into the compression chamber through the air supply valve of the piston is compressed in the compression chamber and discharged to the outside through the exhaust valve of the cylinder head.

4 shows a schematic diagram and a cross-sectional view of a fourth embodiment of a linear motor compressor according to the invention. The difference between the compressor of this embodiment and the compressor of the embodiment of FIG. 2 is that an electromagnet for applying a thrust to the permanent magnet is further provided inside the cylindrical permanent magnet.

In this embodiment, the compressor is inserted into one side of the cylinder 211, the cylinder 211, the piston 212 is installed to enable reciprocating movement, and is fixed to the other side of the cylinder 211 between the cylinder and the piston 212 The cylinder head 213 which forms the compression chamber CV in the inside is included. In addition, an exhaust hole 213a is formed in the cylinder head 213, and an exhaust valve 214 is provided in the exhaust hole 213a. The piston 212 is hollow, and an intake hole 212a having a reduced diameter is formed at an end of the side inserted into the cylinder, and an intake valve 215 is provided in the intake hole 212a. Although not shown in detail, the intake valve 215 is opened when the piston 212 backwards and the pressure in the compression chamber CV is lower than a predetermined value so that the working fluid is introduced therein, and the piston 212 is advanced. It is intended to be closed. In addition, the exhaust valve 214 is closed when the piston 212 is reversed, and when the piston 212 is moved forward and the pressure in the compression chamber (CV) is a predetermined value or more, the compressed working fluid is discharged It is supposed to be.

The linear motor has a cylindrical permanent magnet 227 fixed in close contact with the permanent magnet support 228, and gaps 240 with different magnetic poles 227a and 227b on the outer circumferential surface of the permanent magnet 227 and at regular intervals. A pair of first and second electromagnets 223 and 226 disposed thereon, and a pair of third and third magnets arranged with different magnetic poles 227a and 227b and a constant gap 240 'on the inner circumferential surface of the permanent magnet 227; Fourth electromagnets 323 and 326. Permanent magnet support 228 is made of a non-magnetic material such as aluminum, one side is fixed so that the piston 212 is communicated through the hole 212b, the other side is formed with a through hole 280, the side of the refrigerant from the outside A hole 228a into which is introduced is formed. In this embodiment, the hole 228a is formed in the permanent magnet support 228 as an example, but is not limited thereto. The piston and the permanent magnet support are blocked, and a hole is formed at the side of the piston. It is also possible to introduce refrigerant.

In addition, the through hole 280 is formed with a guide portion 228b extending from the through hole 280. The guide portion 228b is for guiding the support shaft described below. The permanent magnet 227 of this embodiment has a cylindrical shape as shown in FIG. 4 and is fixed to the permanent magnet support 228 so that the center axis coincides with the center axis of the reciprocating direction of the piston 212.

Since the first electromagnet 223 and the second electromagnet 226 are the same as the embodiment shown in FIG. 2, detailed description of the first electromagnet 223 and the second electromagnet 226 is omitted.

The third electromagnet 323 and the fourth electromagnet 326 are cylindrical and are disposed adjacent to each other in the axial direction, and the third electromagnet 323 is formed by any one magnetic pole 227a of the permanent magnet 227. The fourth electromagnet 326 is accommodated in the hollow, and the fourth electromagnet 326 is accommodated in the other magnetic pole 227b. In addition, each of the third electromagnet 323 and the fourth electromagnet 326 may have a third core 322 and a fourth core having an outer circumferential surface spaced apart from the inner circumferential surface of the permanent magnet 227 at a predetermined interval 240 ′. 325 and a third coil 321 and a fourth coil 324 wound inside the third core 322 and the fourth core 325. In addition, slots 322c and 325c are formed in the circumferential direction of the third core 322 and the fourth core 325 so that a pair of different magnetic pole surfaces are formed on the outer circumferential surface when current flows through the coil. The third core 322 and the fourth core 325 are formed by stacking ferromagnetic metal plates from which portions in which coils are wound and portions in which slots are formed are removed. In addition, the slots 322c and 325c formed in the respective cores 322 and 325 are formed in the center of the longitudinal direction of each core, and the lengths of the cores 322 and 325 of the respective electromagnets 323 and 326 are It has a length substantially the same as the length of the cylindrical permanent magnet 227. In addition, the elasticity of the spring 230 is adjusted so that the permanent magnet 227 is located slightly away from the center of the pair of electromagnets 323 and 326 in the stationary state. In the linear motor of the present embodiment, as shown in FIG. 8, the permanent magnets 227 magnetized with different magnetic poles in the longitudinal direction are disposed along the reciprocating direction of the piston 212, and coils wound in opposite directions to each other. As shown in FIG. 4B, the first electromagnet 223 and the second electromagnet 226 disposed outside the permanent magnet 227 and the inside of the permanent magnet 227 are disposed. The third electromagnet 323 and the fourth electromagnet 326 are adapted to apply an alternating thrust in and out of the permanent magnet 227. Therefore, it is possible to apply an increased thrust than the embodiment shown in Figure 2, it is easy to manufacture a large-capacity compressor.

In addition, the linear motor compressor of this embodiment is firmly fixed to the compressor 210 and the linear motor 220 by the cylinder housing 250 and the housing cover 260. The cylinder 211 and the cylinder head 213 are fixed by inserting a part of the piston protruding from the hole 252 on one side of the housing 250. The cylinder housing 250 and the housing cover 260 have a disk shape, and the first electromagnet 223 and the second electromagnet 226 are inserted into and fixed between each other. The housing 250 and the housing cover 260 fixed in close contact with the cores 222 and 225 of the electromagnets 223 and 226 are made of non-magnetic aluminum. A support shaft 262 is further installed at the center of the housing cover 260, and one side of the support shaft 262 is inserted into and fixed to the fixing groove 263. The other side of the fixed shaft 262 supports the cores 322 and 325 of the third and fourth electromagnets 323 and 326 installed inside the permanent magnet support 228, so that the permanent magnet support 228 is Rotate in the longitudinal direction. The fixed shaft 262 is made of a non-magnetic material by the third and fourth cores (322,325) to be fixed in close contact with the other side.

In addition, the first bearing 271 may be easily moved to the piston 212 along the longitudinal direction of the fixed shaft 262 at a portion where the through-hole 280 of the permanent magnet support 228 and the fixed shaft 262 contact. ) And a second bearing 272 installed to facilitate the swinging of the piston 212 at a portion contacting the piston 212 of the support hole 252 of the housing 250.

In addition, one end of the first to fourth springs 231, 232, 233, 234 is supported inside the cylinder housing 250, and the other end is supported on the permanent magnet support 228.

In the present embodiment, the third coil 321 and the fourth coil 324 are wound in opposite directions as indicated by the current direction symbol in FIG. Accordingly, when AC power of the same phase is supplied to each of the electromagnets 323 and 326, the third electromagnets disposed in parallel with the magnetic poles 227a and 227b of the permanent magnet 227 and a constant gap 240 ′ interposed therebetween. The magnetic poles 322a and 322b of 323 and the magnetic poles 325a and 325b of the fourth electromagnet 326 are alternately formed with the same frequency as the AC power source. When the magnetic poles 322a and 322b of the third electromagnet 323 are excited to the S poles 322a and N poles 322b in order from the AC power supplied in a phase, the magnetic poles 325a of the neighboring fourth electromagnets 326. , 325b is reversed to N-pole 325b-S-pole 325a. Therefore, when an alternating current of the same phase is supplied to each of the electromagnets 323 and 326 in the stopped state, the magnetic poles 322b and 325a of the electromagnet facing the magnetic poles 227a and 227b of the permanent magnet 227 are all N. Since the pole, the magnetic force and the repulsive force is applied to the magnetic poles 227a and 227b of the permanent magnet 227, respectively, to apply a thrust pushing the permanent magnet in one direction. When the permanent magnet 227 moves in one direction due to thrust (assuming that the permanent magnet 227 moves in the right direction), the magnetic pole 325a of the third electromagnet 326 adjacent to the direction in which the permanent magnet 227 moves is also a permanent magnet. Manpower is added to (227). The piston 212 connected to the permanent magnet 227 is moved to the right by the applied thrust. At this time, the kinetic energy of the piston 212 is stored as elastic energy in the resonant spring 231. When the phase of the AC power is reversed, the polarities of the magnetic poles 322a, 322b, 325a, and 325b of the electromagnets 323 and 326 are also reversed, and the permanent magnet 227 moves in the opposite direction to the movement direction of the permanent magnet 227. Thrust acts on the piston to move the piston 212 to the left. Therefore, when AC power is continuously applied to each of the electromagnets 323 and 326, the polarity of the magnetic pole of each of the electromagnets 323 and 326 is changed to the same frequency as that of the AC power and applied to the permanent magnet 227. Losing thrust is also alternating with the same frequency as the AC power source. Therefore, the piston 212 connected to the permanent magnet 227 is reciprocated at the same frequency as the AC power source to compress the working fluid sucked through the intake valve 215 into the compression chamber CV to exhaust valve 214. It is discharged to the outside through.

In addition, as shown in FIG. 7, each of the first to fourth coils has a power source connected in parallel, and when power is applied to coils of electromagnets facing each other around a permanent magnet, magnetic flux in the same direction is generated. 4A, the center of the slot 325c of the third electromagnet 323 facing the slot 220a of the first electromagnet 220 and the permanent magnet 227 as shown in FIG. 4 (a). The axes are arranged to coincide. In addition, the fourth electromagnet 326 facing the second electromagnet 226 is also arranged so that the slots 226c and 322c coincide with each other. Therefore, the first electromagnet 220, the third electromagnet 323, and the second electromagnet 226 and the fourth electromagnet 326 shown in FIG. 4 have the same polarity when the opposite magnetic poles are applied. By floating, the thrust can be increased in and out of the cylindrical permanent magnet.

 When the working fluid is used as a refrigerant such as a freon gas in the linear motor compressor of the present invention, it can be used as a compressor of a refrigerating or refrigerating device, and when using air, it can be used as a compressor of a device for supplying high pressure air.

According to the present invention, a permanent magnet is connected to the piston so as to reciprocate with the piston and has a different magnetic pole along the reciprocating direction of the piston, and a plurality of electromagnets arranged to apply alternating thrust to the permanent magnet. It provides a linear motor compressor having a.

In addition, since the permanent magnet is provided in a hollow cylindrical shape and an electromagnet is installed inside and outside the permanent magnet, thrust is applied, thereby making it easy to manufacture a high capacity compressor.

Since the linear motor compressor according to the present invention does not require a separate auxiliary core, it is compact, and the coercive force of the permanent magnet can be maximized, so that the output can be increased as compared with the conventional linear motor compressor.

An embodiment of the present invention described above and illustrated in the drawings should not be construed as limiting the technical spirit of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those skilled in the art can change and change the technical idea of the present invention in various forms. Therefore, such improvements and modifications will fall within the protection scope of the present invention, as will be apparent to those skilled in the art.

Claims (13)

A mover having permanent magnets formed with different magnetic poles along the rotational direction, A stator having a fixed iron core and a plurality of electromagnets formed by winding a coil around the fixed iron core; An elastic member for pivotably supporting the movable member along the swinging direction of the movable member, When the plurality of electromagnets of the stator is excited by an alternating current, each magnetic pole polarity is arranged along the swinging direction so that the magnetic poles of the permanent magnets exert alternating thrust on the permanent magnets by the attraction force and the repulsive force. Linear motor. The method of claim 1, The permanent magnet is a cylindrical shape, The plurality of electromagnets, One pole of the permanent magnet is accommodated in the hollow, and a slot is formed in the circumferential direction so that a pair of poles are formed on the inner circumferential surface of the hollow spaced at regular intervals from the outer circumference of the accommodated permanent magnet, and laminated with a ferromagnetic plate. A first electromagnet having a first core, and a first coil wound around the first core, The other one magnetic pole of the permanent magnet is accommodated inside the hollow, and a slot is formed in the circumferential direction so that a pair of magnetic poles are formed on the inner circumferential surface of the hollow spaced at regular intervals from the outer circumferential surface of the received permanent magnet and laminated with a ferromagnetic plate And a second electromagnet having a second core and a second coil wound in a direction opposite to the first coil inside the second core. The method of claim 1, The permanent magnet is a cylindrical shape, The plurality of electromagnets, Any one magnetic pole of the permanent magnet is accommodated in the hollow formed, a slot is formed in the circumferential direction so that a pair of magnetic poles are formed on the outer peripheral surface spaced at regular intervals from the inner peripheral surface of the receiving permanent magnet and laminated with a ferromagnetic plate A third electromagnet having a third core, and a third coil wound inside the third core, The other one magnetic pole of the permanent magnet is accommodated in the hollow formed, a slot is formed in the circumferential direction to form a pair of magnetic poles on the outer peripheral surface spaced at regular intervals from the inner peripheral surface of the receiving permanent magnet and laminated with a ferromagnetic plate And a fourth electromagnet having a fourth core, and a fourth coil wound inside the fourth core in a direction opposite to the third coil. The method of claim 2, The plurality of electromagnets, A slot is formed in the circumferential direction and is formed in a circumferential direction such that a pair of magnetic poles is formed in the hollow formed by the magnetic pole accommodated in the first electromagnet of the permanent magnet, and the outer peripheral surface spaced at regular intervals from the inner peripheral surface of the permanent magnet. A third electromagnet having a third core laminated with a plate, a third coil wound inside the third core, A slot is formed in the circumferential direction and is formed in a circumferential direction such that a pair of magnetic poles is formed in the hollow formed by the magnetic pole accommodated in the second electromagnet of the permanent magnet, and the outer peripheral surface spaced at regular intervals from the inner peripheral surface of the permanent magnet. And a fourth electromagnet having a fourth core stacked in the second core and a fourth coil wound in a direction opposite to the third coil in the fourth core. The slot of the first core of the first electromagnet and the slot of the third core of the third electromagnet are located in the same plane perpendicular to the swinging direction, and the slot of the second core of the second electromagnet and the fourth core of the fourth electromagnet The slot of is located in the same plane perpendicular to the direction of rotation, The coils wound on the first core and the coils wound on the third core are respectively wound to form magnetic fluxes in the same direction, and the coils wound on the fourth cores and the coils wound on the fourth cores respectively form magnetic fluxes in the same direction. A linear motor, characterized in that wound as possible. The method of claim 2, The first electromagnet and the second electromagnet are disposed adjacent to the outer circumferential side of the permanent magnet, and slots formed in the cores of the first and second electromagnets are formed in the center of the longitudinal direction of each core, respectively. The length of the core of the first and second electromagnet of the linear motor, characterized in that substantially equal to the length of the permanent magnet of the cylinder shape. The method of claim 4, wherein The first electromagnet and the second electromagnet are disposed adjacent to the outer circumferential side of the permanent magnet, and slots formed in the cores of the first and second electromagnets are formed in the center of the longitudinal direction of each core, respectively. The length of the core of the first and second electromagnets is substantially the same as the length of the cylindrical permanent magnet, The third electromagnet and the fourth electromagnet are disposed adjacent to the inner circumferential side of the permanent magnet, and slots formed in the cores of the third and fourth electromagnets are formed in the center of the longitudinal direction of each core, respectively. The length of the core of the third and fourth electromagnet of the linear motor, characterized in that substantially the same as the length of the permanent magnet of the cylindrical shape. A cylinder, a piston inserted into one side of the cylinder to allow reciprocating movement, a cylinder head fixed to the other side of the cylinder to form a compression chamber between the cylinder and the piston, and into the compression chamber when the piston is retracted A compressor including an intake valve installed to suck the working fluid, and an exhaust valve installed to discharge the compressed working fluid in the compression chamber when the piston is advanced; A mover fixed to the piston and having a permanent magnet in a cylindrical shape in which different magnetic poles are formed along a swinging direction of the piston; One magnetic pole of the permanent magnet is accommodated in the hollow formed, a slot is formed in the circumferential direction to form a pair of magnetic poles on the outer circumferential surface spaced at regular intervals from the inner circumferential surface of the permanent magnet to accommodate the ferromagnetic plate A third electromagnet having a stacked third core, a third coil wound around the inside of the third core, and a hollow magnet formed by the other magnetic pole of the permanent magnet, the permanent magnet being accommodated therein; A fourth core stacked in a circumferential direction and laminated with a ferromagnetic plate such that a pair of magnetic poles are formed on the outer circumferential surface spaced at regular intervals from the inner circumferential surface thereof, and wound in a direction opposite to the third coil inside the fourth core. A stator having a fourth electromagnet having a fourth coil, An elastic member for pivotably supporting the movable member along the swinging direction of the movable member, The third electromagnets and the fourth electromagnets of the stator are arranged along the rotational direction so that when the magnetic poles are excited by an alternating current, the magnetic poles of the magnetic poles exert an alternating thrust on the permanent magnets by the magnetic poles and the attractive force and the repulsive force of the permanent magnets. Linear motor compressor, characterized in that. The method of claim 7, wherein The stator, One pole of the permanent magnet is accommodated in the hollow, and a slot is formed in the circumferential direction so that a pair of poles are formed on the inner circumferential surface of the hollow spaced at regular intervals from the outer circumference of the accommodated permanent magnet, and laminated with a ferromagnetic plate. A first electromagnet having a first core, and a first coil wound around the first core, The other one magnetic pole of the permanent magnet is accommodated inside the hollow, and a slot is formed in the circumferential direction so that a pair of magnetic poles are formed on the inner circumferential surface of the hollow spaced at regular intervals from the outer circumferential surface of the received permanent magnet and laminated with a ferromagnetic plate And a second electromagnet having a second core and a second coil wound in a direction opposite to the first coil inside the second core. The slot of the first core of the first electromagnet and the slot of the third core of the third electromagnet are located in the same plane perpendicular to the swinging direction, and the slot of the second core of the second electromagnet and the fourth core of the fourth electromagnet The slot of is located in the same plane perpendicular to the direction of rotation, The coils wound on the first core and the coils wound on the third core are respectively wound to form magnetic fluxes in the same direction, and the coils wound on the fourth cores and the coils wound on the fourth cores respectively form magnetic fluxes in the same direction. A linear motor compressor, characterized in that wound as possible. The method of claim 8, The first electromagnet and the second electromagnet are disposed adjacent to the outer circumferential side of the permanent magnet, and slots formed in the cores of the first and second electromagnets are formed in the center of the longitudinal direction of each core, respectively. The length of the core of the first and second electromagnets is substantially the same as the length of the cylindrical permanent magnet, The third electromagnet and the fourth electromagnet are disposed adjacent to the inner circumferential side of the permanent magnet, the slot formed in the core of each of the third and fourth electromagnet is formed in the center of the longitudinal direction of each core, The length of the core of each of the third and fourth electromagnets is substantially the same as the length of the cylindrical permanent magnet. The method according to any one of claims 7 to 9, The cylinder head is formed with a discharge hole for discharging the working fluid in the compression chamber, The piston has an inlet hole for introducing the working fluid into the compression chamber, The exhaust valve is provided in the discharge hole formed in the cylinder head, The intake valve is a linear motor compressor, characterized in that installed in the inlet hole of the piston. The method of claim 10, The mover further includes a cylindrical permanent magnet support for fixing a cylindrical permanent magnet, And the third electromagnet and the fourth electromagnet are installed in the permanent magnet support. The method of claim 11, One side of the permanent magnet support is fixed to the piston, the other side is formed through holes, A support hole for supporting the piston is inserted into one side is formed, and further comprises a housing for supporting each core of the first and second electromagnet therein, Inside the housing, one side is fixed to the other side of the housing in the center in the longitudinal direction, the other side is inserted into the through hole of the permanent magnet support, each of the third and fourth electromagnets installed in the permanent magnet support And a support shaft mounted to support the core and allow the permanent magnet support to swing longitudinally. The method of claim 12, A first bearing provided at a portion where the through hole of the permanent magnet support and the fixed shaft is in contact with the piston to facilitate swinging along the longitudinal direction of the fixed shaft; And a second bearing provided at a portion of the housing in contact with the piston of the support hole to facilitate swinging of the piston.

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