KR20150040050A - A linear compressor - Google Patents

Abstract

The present invention relates to a linear compressor. According to an embodiment of the present invention, the linear compressor comprises: a shell having a refrigerant suction unit; a cylinder provided inside the shell; a piston which reciprocates inside the cylinder; a motor assembly providing a driving force to move the piston; a magnet assembly transferring the driving force generated from the motor assembly to the piston, and having a permanent magnet; and a frame combined on the cylinder, supporting the motor assembly, and having a contact unit which can be interrupted by the permanent magnet when the piston reciprocates.

Description

[0001] The present invention relates to a linear compressor,

The present invention relates to a linear compressor.

Generally, a compressor is a mechanical device that receives power from an electric motor such as an electric motor or a turbine and compresses air, refrigerant or various other operating gases to increase the pressure. The compressor is used for a household appliance such as a refrigerator and an air conditioner, It is widely used throughout.

Such a compressor is broadly classified into a reciprocating compressor that compresses the refrigerant while linearly reciprocating the piston inside the cylinder so as to form a compression space in which a working gas is sucked and discharged between the piston and the cylinder. A rotary compressor for compressing the refrigerant while the roller is eccentrically rotated along the inner wall of the cylinder and a compression space for sucking and discharging the working gas between the roller and the cylinder, a scroll compressor in which a compression space in which an operating gas is sucked and discharged is formed between a fixed scroll and a fixed scroll and the orbiting scroll rotates along the fixed scroll to compress the refrigerant.

In recent years, among the reciprocating compressors, there has been developed a linear compressor in which a piston is directly connected to a driving motor that reciprocates linearly, so that compression efficiency can be improved without mechanical loss due to motion switching and a simple structure is constructed.

Normally, the linear compressor is configured to suck and compress the refrigerant while discharging the refrigerant while moving the piston in the sealed shell by reciprocating linear motion within the cylinder by the linear motor.

The linear motor is configured such that a permanent magnet is positioned between an inner stator and an outer stator, and the permanent magnet is driven to linearly reciprocate by the mutual electromagnetic force between the permanent magnet and the inner (or outer) stator. As the permanent magnet is driven in the state of being connected to the piston, the piston linearly reciprocates in the cylinder, sucks the refrigerant, compresses the refrigerant, and discharges the refrigerant.

1 and 2, the structure of a conventional linear compressor 1 is shown.

The conventional linear compressor 1 includes a cylinder 6, a piston 7 linearly reciprocating in the cylinder 6, and a linear motor for imparting a driving force to the piston 7. The cylinder (6) can be fixed by a frame (5). The frame 5 may be integrally formed with the cylinder 6 or may be fastened by a separate fastening member.

The linear motor includes an outer stator 2 fixed to the frame 5 and disposed to surround the cylinder 6, an inner stator 3 disposed to be spaced inward from the outer stator 2, And a permanent magnet 10 positioned in the space between the outer stator 2 and the inner stator 3. [ In the outer stator (2), the coil (4) can be wound.

The linear compressor (1) further includes a magnet frame (11). The magnet frame transmits the driving force of the linear motor to the piston, and the permanent magnet 10 may be installed on the outer circumferential surface of the piston.

The linear compressor 1 further includes a supporter 8 for supporting the piston 7 and a motor cover 9 coupled to one side of the outer stator 2.

A spring (not shown) may be coupled between the supporter 8 and the motor cover 9. The spring may be configured to adjust the natural frequency so that the piston (7) can resonate.

The linear compressor (1) includes a muffler (12) extending outwardly from the inside of the piston (7). The muffler 12 can reduce the noise generated during the flow of the refrigerant.

With such a configuration, when the linear motor is driven, the driving assembly of the magnet frame 11, the permanent magnet 10, the piston 7, and the supporter 8 reciprocates integrally.

FIG. 1 shows a state in which the piston 7 is at a position where the refrigerant is not compressed, that is, at a bottom dead center (BDC), and FIG. 2 shows a state in which the piston 7 compresses the refrigerant, Top Dead Center, TDC). The piston (7) performs reciprocating linear motion between the bottom dead center and the top dead center.

The reciprocating motion of the drive assembly 7, 8, 10, 11 may be performed by electrical control of the linear motor and structural resilient control of the spring. In particular, the assembly can be controlled so as not to interfere with the fixture provided inside the linear compressor 1, for example, the frame 5, the cylinder 6 or the motor cover 9 during the reciprocating motion .

However, an emergency situation may occur where control of the drive assembly is disabled or limited during driving of the linear compressor. When the emergency situation occurs, interference or collision may occur between the drive assembly and the fixture.

In this case, in order to ensure the reliability of the compressor, the structure of the compressor may be designed so that portions where the breakage of the drive assembly or the fixture may occur at a small amount may come into contact with or collide with each other.

On the other hand, the portion where the breakage may be less likely to occur may be a relatively large portion of the drive assembly. The inertial force of a reciprocating object is proportional to the mass of the object. When a relatively large mass is collided, the inertia of the other mass is small and the possibility of breakage is low.

On the other hand, when a relatively small portion of a reciprocating object is collided, the inertial force of the other portion having a large mass is large, so that there is a high possibility that the object is damaged. Thus, in an emergency situation, the portion of the drive assembly that is designed to be collisionally determined is a relatively large mass portion.

In the case of the conventional linear compressor 1, the permanent magnet 10 may be made of a rare earth magnet (neodymium magnet or ND magnet). While the ND magnet has a very high magnetic flux density, it is very expensive and uses a small amount of magnets. Therefore, the mass of the permanent magnet 10 is formed not to be large.

On the other hand, the piston 7 or the supporter 8 of the drive assembly is formed to have a large mass. Therefore, in the conventional linear compressor 1, when a collision occurs between reciprocating movements of the drive assembly, collision between the piston 7 and the cylinder 6, or between the supporter 8 and the motor cover 9, Lt; / RTI >

For example, in Fig. 2, when the piston 7 is at the top dead center position, the piston 7 may contact or impinge on the end of the cylinder 7. In this state, the permanent magnet 10 may not contact or collide with the frame 5. [

As another example of the prior art, although not shown in the drawings, at least a part of the supporter 8 is contacted or collided with the motor cover 9 when the piston 7 is at the top dead center position, The permanent magnet 10 may not contact or collide with the frame 5.

According to this conventional technique, since the price of the ND magnet is very high, there is a problem that the manufacturing cost of the linear compressor is excessively increased when the ND magnet is used as the permanent magnet.

In addition, there is a problem that the magnitude of the magnetic flux leaking from the ND magnet is large and the operation efficiency of the compressor is lowered.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above problems, and it is an object of the present invention to provide a linear compressor which has improved compression efficiency and reliability.

A linear compressor according to an embodiment of the present invention includes: a shell having a refrigerant suction portion; A cylinder provided inside the shell; A piston reciprocating within the cylinder; A motor assembly for providing a driving force for the movement of the piston; A magnet assembly that transmits a driving force generated from the motor assembly to the piston, and includes a permanent magnet; And a frame coupled to the cylinder to support the motor assembly and having a contact portion that can interfere with the permanent magnet in reciprocating movement of the piston.

Further, in the process of reciprocating the piston, when the piston is in the first position, the end of the permanent magnet is spaced apart from the contact by a first distance.

The first position is a bottom dead center (BDC) of the piston, and at a bottom dead center of the piston, the refrigerant is sucked through the coolant suction unit and flows into the cylinder.

Further, in the process of reciprocating the piston, when the piston is in the second position, the end portion of the permanent magnet is in contact with or comes into contact with the contact portion.

The second position is a top dead center (TDC) of the piston, and the refrigerant compressed inside the cylinder at the top dead center of the piston is discharged to the outside of the cylinder.

In addition, the magnet assembly includes a cylindrical magnet frame; An engaging plate coupled to one side of the magnet frame and coupled to one end of the permanent magnet; And a support member coupled to the other end of the permanent magnet.

Further, the support member is disposed at a position where it can collide with or come into contact with the contact portion.

The flange further includes a flange extending radially outwardly of the piston, the flange being adapted to move toward or away from the end of the cylinder in the reciprocating motion of the piston .

Further, when the piston is in the first position, the flange is spaced apart from the end of the cylinder by a second spacing distance, and the first spacing distance is smaller than the second spacing distance.

Further, when the piston is in the second position, the flange is spaced apart from the end of the cylinder by a fourth spacing distance, and the fourth spacing distance is smaller than the second spacing distance.

A supporter coupled to the outside of the flange of the piston and supporting the piston; A motor cover for supporting one side of the motor assembly; And a spring provided between the supporter and the motor cover.

Further, when the piston is in the first position, a third distance in the radial direction is formed between at least a part of the supporter and the motor cover.

Further, when the piston is in the second position, a fifth gap in the radial direction is formed between at least a part of the supporter and the motor cover, and the fifth gap is equal to the third gap Is smaller than the third spacing distance.

The contact portion is formed at a point where the imaginary line extending the permanent magnet and the frame meet.

Further, the permanent magnet is made of ferrite material.

According to the present invention, since the permanent magnet is made of ferrite material, the magnetic flux density is smaller than that of the conventional ND magnet, and the amount of magnetic flux leaked from the permanent magnet is reduced, so that the operating efficiency of the compressor can be improved. Further, the permanent magnets are made of a ferrite material, which is advantageous in that the manufacturing cost of the compressor can be reduced.

Further, when an emergency occurs, the magnet assembly having a relatively large mass among the reciprocating drive assemblies is configured to come into contact with or collide with the stationary body, so that damage to the drive assembly or the stationary body can be prevented.

In addition, since the cylinder and the piston are made of a non-magnetic material, particularly aluminum, leakage of the magnetic flux generated in the motor assembly to the outside of the cylinder can be prevented, thereby improving the efficiency of the compressor.

1 and 2 are sectional views showing a configuration of a conventional linear compressor.
3 is a cross-sectional view illustrating an internal configuration of a linear compressor according to an embodiment of the present invention.
4 is a perspective view showing a magnet assembly of a linear compressor according to an embodiment of the present invention.
5 is a cross-sectional view taken along line I-I 'of FIG.
6 is a schematic diagram showing the construction and mass of a drive assembly according to an embodiment of the present invention.
7 is a cross-sectional view showing the internal configuration of a linear compressor when the piston according to the embodiment of the present invention is in the first position.
8 is a cross-sectional view showing the internal configuration of the linear compressor when the piston according to the embodiment of the present invention is in the second position.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. It is to be understood, however, that the spirit of the invention is not limited to the embodiments shown and that those skilled in the art, upon reading and understanding the spirit of the invention, may easily suggest other embodiments within the scope of the same concept.

3 is a cross-sectional view illustrating an internal configuration of a linear compressor according to an embodiment of the present invention.

3, a linear compressor 100 according to an embodiment of the present invention includes a cylinder 120 provided in a shell 100a and a reciprocating linear motion And a motor assembly 200 for imparting a driving force to the piston 130. The piston 130 may be a piston, The shell 100a may be constructed by combining an upper shell and a lower shell.

The cylinder 120 may be made of an aluminum material (aluminum or aluminum alloy) which is a non-magnetic material.

Since the cylinder 120 is made of an aluminum material, the magnetic flux generated in the motor assembly 200 can be prevented from being transmitted to the cylinder 120 and leaking to the outside of the cylinder 120. The cylinder 120 may be formed by an extrusion rod processing method.

The piston 130 may be made of an aluminum material (aluminum or aluminum alloy) which is a non-magnetic material. Since the piston 130 is made of an aluminum material, the magnetic flux generated in the motor assembly 200 can be prevented from being transmitted to the piston 130 and leaking to the outside of the piston 130. The piston 130 may be formed by a forging method.

The material composition ratio of the cylinder 120 and the piston 130, that is, kind and composition ratio, may be the same. Since the piston 130 and the cylinder 120 are made of the same material (aluminum), the coefficients of thermal expansion become equal to each other. Since the piston 130 and the cylinder 120 have the same thermal expansion coefficient during the operation of the linear compressor 100 and the inside of the shell 100 has a high temperature (about 100 ° C) And the cylinder 120 can be thermally deformed by the same amount.

As a result, it is possible to prevent the piston 130 and the cylinder 120 from being thermally deformed in different sizes or directions to cause interference with the cylinder 120 between the movement of the piston 130 and the piston 130.

The shell 100a includes a suction portion 101 through which the refrigerant flows and a discharge portion 105 through which the refrigerant compressed in the cylinder 120 is discharged. The refrigerant sucked through the suction portion 101 flows into the piston 130 through the suction muffler 270.

The refrigerant sucked through the suction portion 101 flows into the piston 130 through the suction muffler 270. As the refrigerant passes through the suction muffler 270, noise having various frequencies can be reduced.

A compression space P in which the refrigerant is compressed by the piston 130 is formed in the cylinder 120. A suction hole 131a for introducing the refrigerant into the compression space P is formed in the piston 130 and a suction hole 131a for selectively opening the suction hole 131a is formed at one side of the suction hole 131a. A valve 132 is provided.

At one side of the compression space (P), there is provided a discharge valve assembly (170, 172, 174) for discharging refrigerant compressed in the compression space (P). That is, the compression space P is understood as a space formed between one end of the piston 130 and the discharge valve assemblies 170, 172, and 174.

The discharge valve assembly (170, 172, 174) is provided with a discharge cover (172) for forming a refrigerant discharge space and a discharge valve And a valve spring 174 provided between the discharge valve 170 and the discharge cover 172 to apply an elastic force in the axial direction. Here, the "axial direction" can be understood as a direction in which the piston 130 reciprocates, that is, a lateral direction in FIG.

The suction valve 132 is formed on one side of the compression space P and the discharge valve 170 may be provided on the other side of the compression space P, that is, on the opposite side of the suction valve 132.

When the pressure in the compression space P is lower than the discharge pressure and becomes lower than the suction pressure in the reciprocating linear motion of the piston 130 in the cylinder 120, the suction valve 132 is opened, Is sucked into the compression space (P). On the other hand, when the pressure in the compression space P becomes equal to or higher than the suction pressure, the refrigerant in the compression space P is compressed while the suction valve 132 is closed.

On the other hand, when the pressure in the compression space P becomes equal to or higher than the discharge pressure, the valve spring 174 is deformed to open the discharge valve 170. The refrigerant is discharged from the compression space P, And is discharged to the discharge space of the cover 172.

The refrigerant in the discharge space flows into the loop pipe 178 through the discharge muffler 176. The discharge muffler 176 can reduce the flow noise of the compressed refrigerant, and the loop pipe 178 guides the compressed refrigerant to the discharge portion 105. The loop pipe 178 is connected to the discharge muffler 176 and extends in a curved shape, and is coupled to the discharge part 105.

The linear compressor (10) further includes a frame (110). The frame 110 is configured to fix the cylinder 120 and may be integrally formed with the cylinder 120 or may be fastened by a separate fastening member.

The discharge cover 172 and the discharge muffler 176 may be coupled to the frame 110. The frame 110 may be positioned behind the permanent magnet 350.

The motor assembly 200 includes an outer stator 210 fixed or supported on the frame 110 so as to surround the cylinder 120 and an inner stator 210 spaced inward from the outer stator 210. [ And a permanent magnet 350 positioned between the outer stator 210 and the inner stator 220.

The permanent magnets 350 can reciprocate linearly by mutual electromagnetic force between the outer stator 210 and the inner stator 220. The permanent magnet 350 includes a plurality of magnets having one pole or three poles. The permanent magnet 350 may be made of a relatively inexpensive ferrite material.

The permanent magnet 350 is mounted on the outer circumferential surface of the magnet frame 310 of the magnet assembly 300 and the coupling plate 330 is brought into contact with one end of the permanent magnet 350. The permanent magnet 350 and the coupling plate 330 may be coupled by a fixing member 360.

The coupling plate 330 may be formed of a non-magnetic material. For example, the coupling plate 330 may be made of stainless steel.

The coupling plate 330 covers one open end of the magnet frame 310 and can be coupled to the flange 134 of the piston 130. For example, the coupling plate 330 and the flange 134 may be bolted together.

The flange 134 is understood to extend radially from the end of the piston 130 and may be proximate to the end of the cylinder 120 during the reciprocating motion of the piston 130, 120). ≪ / RTI >

As the permanent magnet 350 linearly moves, the piston 130, the magnet frame 310, and the coupling plate 330 can linearly reciprocate in the axial direction together with the permanent magnet 350.

The outer stator 210 includes a coil winding body 213 and a stator core 211.

The coil windings 213 and 215 include a bobbin 213 and a coil 215 wound around the bobbin 213 in the circumferential direction. The cross section of the coil 215 may have a polygonal shape, for example, a hexagonal shape.

The stator core 211 is formed by stacking a plurality of laminations in the circumferential direction, and may be arranged to surround the coil winding bodies 213 and 215.

When a current is applied to the motor assembly 200, a current flows through the coil 215, a flux is formed around the coil 215 due to the current flowing through the coil 215, Flows along the outer stator 210 and the inner stator 220 while forming a closed circuit.

The magnetic flux flowing along the outer stator 210 and the inner stator 220 and the magnetic flux of the permanent magnet 230 may interact to generate a force for moving the permanent magnet 230.

A stator cover 240 is provided at one side of the outer stator 210. One end of the outer stator 210 may be supported by the frame 110 and the other end may be supported by the stator cover 240. The stator cover 240 may be referred to as a "motor cover ".

The inner stator 220 is fixed to the outer periphery of the cylinder 120 on the inner side of the magnet frame 310. The inner stator 220 is formed by stacking a plurality of laminations in the circumferential direction from the outside of the cylinder 120.

The linear compressor 10 further includes a supporter 135 for supporting the piston 130 and a back cover 115 extending from the piston 130 toward the suction portion 101. The supporter 135 is coupled to the outside of the coupling plate 330. The back cover 115 may be disposed to cover at least a portion of the suction muffler 140.

The linear compressor 10 includes a plurality of springs 151 and 155 which are resilient members whose natural frequencies are adjusted so that the piston 130 can resonate.

The plurality of springs 151 and 155 are provided with a first spring 151 supported between the supporter 135 and the stator cover 240 and a second spring 151 supported between the supporter 135 and the back cover 115. [ A spring 155 is included. The elastic modulus of the first spring 151 and the second spring 155 may be the same.

The first spring 151 may be provided on the upper side and the lower side of the cylinder 120 or the piston 130 and the second spring 155 may be provided on the front side of the cylinder 120 or the piston 130, May be provided.

Here, the "forward" can be understood as a direction from the piston 130 toward the suction portion 101. [ That is, the direction from the suction unit 101 to the discharge valve assemblies 170, 172, and 174 may be referred to as "rearward ". This term can be used in the following description as well.

A predetermined oil may be stored on the inner bottom surface of the shell 100a. An oil supply device 160 for pumping oil may be provided under the shell 100a. The oil supply device 160 is operated by the vibration generated as the piston 130 linearly reciprocates to pump the oil upward.

The linear compressor (100) further includes an oil supply pipe (165) for guiding the flow of oil from the oil supply device (160). The oil supply pipe 165 may extend from the oil supply device 160 to a space between the cylinder 120 and the piston 130.

The oil pumped from the oil supply device 160 is supplied to the space between the cylinder 120 and the piston 130 through the oil supply pipe 165 to perform cooling and lubrication.

FIG. 4 is a perspective view showing a magnet assembly of a linear compressor according to an embodiment of the present invention, and FIG. 5 is a cross-sectional view taken along line I-I 'of FIG.

4 and 5, the magnet assembly 300 according to the embodiment of the present invention includes a magnet frame 310 having a substantially cylindrical shape and a permanent magnet 350 installed on the outer circumferential surface of the magnet frame 310. [ .

The inner stator 220, the cylinder 120 and the piston 130 are disposed on the inner side of the magnet frame 310 and the outer stator 210 is disposed on the outer side of the magnet frame 310. (See FIG. 3).

At both side ends of the magnet frame 310, opened openings 311 and 312 are included. The openings 311 and 312 include a first opening 311 formed at one end of the magnet frame 310 and a second opening 312 formed at the other end of the magnet frame 310. In one example, the one end may be an upper end and the other end may be a lower end.

A coupling plate 330 coupled to the flange 134 of the piston 130 is coupled to the magnet frame 310. In detail, the coupling plate 330 may be coupled to one end of the magnet frame 310 to cover the first opening 311.

A support member 315 for supporting the permanent magnet 350 is provided on an outer circumferential surface of the magnet frame 310. The support member 315 is configured to contact one end of the permanent magnet 350 and may be disposed outside the second opening 312.

The other end of the permanent magnet 350 is disposed so as to be in contact with the coupling plate 330. That is, the permanent magnet 350 may be disposed between the coupling plate 330 and the support member 315 to be contactable.

As a result, the permanent magnet 350 can be prevented from being detached from the magnet frame 310 by the coupling plate 330 and the support member 315.

6 is a schematic diagram illustrating the configuration and mass of a drive assembly according to an embodiment of the present invention.

Referring to FIG. 6, the driving assembly according to an embodiment of the present invention includes the magnet assembly 300, the piston assemblies 130, 134, 145, 270, and the supporter 135.

The magnet assembly 300 includes a magnet frame 310, a permanent magnet 350, and a coupling plate 330. The piston assembly 130 includes a piston 130, a flange 134, a balance weight 145, and a suction muffler 270.

The magnet assembly 300 has a mass of M1, and the supporter 135 has a mass of M2. The piston assembly 130, 145, 270 has a mass of M3.

The reason why the mass of the driving assembly is divided into M1, M2 and M3 is that when the driving assembly reciprocates linearly in the forward and backward directions, the fixing assembly inside the linear compressor 100, When a collision occurs with the cylinder 120 or the stator cover 240, the collision is classified according to whether the collision force is directly received or the inertia force is applied due to the impact.

For example, when a portion of the magnet assembly 300, that is, an end portion of the permanent magnet 350, is impacted, the impact force is directly transmitted to the components constituting the magnet assembly 300, and the piston assembly 130 And the supporter 135 may be subjected to an inertial force.

On the other hand, when a collision occurs in a portion of the piston assembly 130, 134, 145, 270, that is, the flange 134, an inertial force may be applied to the magnet assembly 300 and the supporter 135.

When a collision occurs in the supporter 135, an inertial force will act on the magnet assembly 300 and the piston assemblies 130, 134, 145 and 270.

The mass M1 of the magnet assembly 300 may be larger than the mass M2 of the supporter 135 and the mass M3 of the piston assembly. In addition, the M2 may be formed larger than the M3.

Accordingly, the present embodiment allows the magnet assembly 300, which is the largest in mass of the drive assembly, to collide with a predetermined fixture when an emergency situation (control of the drive assembly is impossible or limited) ) Or the piston assemblies (130, 134, 145, 270) are prevented from being separated or damaged by an inertial force.

Hereinafter, a structure in which the magnet assembly 300 can collide with the frame 110 in the linear compressor according to the present embodiment will be described with reference to FIGS. 7 and 8. FIG.

FIG. 7 is a cross-sectional view showing the internal configuration of a linear compressor when the piston is in the first position according to the embodiment of the present invention, and FIG. 8 is a sectional view of the linear compressor when the piston according to the embodiment of the present invention is in the second position. Fig.

7, there is shown a view of the inside of the compressor 100 when the piston 130 according to the embodiment of the present invention is in the first position.

Here, the "first position" is a bottom dead center (BDC) of the piston 130 when the piston 130 moves to the forefront. At the bottom dead center, the refrigerant can be sucked into the compression space (P) formed in front of the piston (130).

When the piston 130 is positioned at the bottom dead center, the rear end of the permanent magnet 350, that is, the support member 315 is separated from the frame 110 by a first separation distance W1 do. Here, a portion of the frame 110 spaced from the support member 315 by W1 forms the contact portion 110a. The contact portion 110a may be formed at an imaginary line extending the permanent magnet 135 and at a point where the frame 110 meets.

The flange 134 of the piston 130 is spaced apart from the front end of the cylinder 120 by a second distance W2.

At least a part of the supporter 135 is spaced apart from the imaginary line extending from the end of the stator cover 240 by the third separation distance W3. Here, at least a part of the supporter 135 means a portion extending forward and backward.

That is, when the piston 130 is at the bottom dead center position, the drive assembly 134, 135, 350 contacts or collides with a fixed body, such as the frame 110, the cylinder 120, or the stator cover 240, It does not.

W1 and W2 represent distances spaced forward and backward, and W3 represents radially distanced distances. And, W1 has a value smaller than W2.

Therefore, when the driving assembly moves backward, if the moving distance of the driving assembly is W1, the end of the permanent magnet 350 may contact or collide with the contact portion 110a. On the other hand, the flange 134 of the piston 130 may not contact or impact the cylinder 120.

8 shows a view of the inside of the compressor 100 when the piston 130 according to the embodiment of the present invention is in the second position.

Here, the "second position" is a top dead center (TDC) of the piston 130 when the piston 130 moves to the rearmost position. At the top dead center, the refrigerant may be discharged from the compression space (P) toward the discharge cover (172).

The rear end of the permanent magnet 350 or the support member 315 collides with the contact portion 110a of the frame 110 when the piston 130 is positioned at the top dead center. That is, a distance between the rear end of the permanent magnet 350 and the contact portion 110a is not formed, and a contact point C1, which is in contact with the end portion of the permanent magnet 350 and the contact portion 110a, have.

Further, the flange 134 of the piston 130 does not come into contact with or collide with the cylinder 120. That is, the flange 134 of the piston 130 is spaced apart from the front end of the cylinder 120 by a fourth separation distance W2 '. W2 'may have a value smaller than W2.

The supporter 135 does not contact or collide with the stator cover 240. That is, at least a portion of the supporter 135 is spaced apart from the imaginary line extending from the end of the stator cover 240 by the fifth separation distance W3 '. W3 'may be equal to or less than W3.

When the piston 130 is at the top dead center position, the end of the permanent magnet 350 of the driving assembly collides with the frame 110, and the supporter 135 and the piston 130 The flange 134 does not contact or collide with the stator cover 240 and the cylinder 120, respectively.

According to such a configuration, when an emergency situation occurs in which the control of the compressor is disabled or restricted, the magnet assembly having a relatively large mass among the drive assemblies is brought into contact with the frame, thereby preventing damage to other components due to the inertia force.

100: Linear compressor 100a: Shell
110: frame 115: back cover
120: cylinder 130: piston
134: flange 135: supporter
151, 155: first and second springs 200: motor assembly
210: outer stator 220: inner stator
240: stator cover 300: magnet assembly
310: Magnet frame 315: Support member
330: coupling plate 350: permanent magnet

Claims (14)

A shell having a refrigerant suction portion;
A cylinder provided inside the shell;
A piston reciprocating within the cylinder;
A motor assembly for providing a driving force for the movement of the piston; And
A magnet assembly that transmits a driving force generated in the motor assembly to the piston and includes a permanent magnet;
A support member provided on the magnet assembly and supporting the end side of the permanent magnet; And
And a frame having a contact portion that is coupled to the cylinder and supports the motor assembly, the contact portion being capable of contacting or colliding with the support member during the reciprocating movement of the piston. The method according to claim 1,
During the reciprocating motion of the piston,
Wherein when the piston is in the first position, the support member is spaced apart from the contact by a first separation distance. 3. The method of claim 2,
Wherein the first position is a bottom dead center (BDC) of the piston,
Wherein the refrigerant is sucked through the refrigerant suction portion and flows into the cylinder at the bottom dead center of the piston. 3. The method of claim 2,
During the reciprocating motion of the piston,
And when the piston is in the second position, the support member contacts or collides with the contact portion. 5. The method of claim 4,
The second position being a top dead center (TDC) of the piston,
Wherein the refrigerant compressed inside the cylinder at the top dead center of the piston is discharged to the outside of the cylinder. The method according to claim 1,
In the magnet assembly,
A cylindrical magnet frame;
And a coupling plate coupled to one side of the magnet frame and coupled to one end of the permanent magnet. 5. The method of claim 4,
Further comprising a flange extending radially outwardly of the piston,
The flange
In the course of reciprocation of the piston, move toward the end of the cylinder or move away from the end of the cylinder. 8. The method of claim 7,
When the piston is in the first position, the flange is spaced apart from the end of the cylinder by a second spacing distance,
Wherein the first separation distance is smaller than the second separation distance. 9. The method of claim 8,
When the piston is in the second position, the flange is spaced from the end of the cylinder by a fourth spacing distance,
And the fourth spacing distance is smaller than the second spacing distance. 5. The method of claim 4,
A supporter coupled to the outside of the flange of the piston and supporting the piston;
A motor cover for supporting one side of the motor assembly; And
And a spring provided between the supporter and the motor cover. 11. The method of claim 10,
When the piston is in the first position,
And a third spacing distance in the radial direction is formed between at least a part of the supporter and the motor cover. 12. The method of claim 11,
When the piston is in the second position,
A fifth spacing distance in the radial direction is formed between at least a portion of the supporter and the motor cover,
Wherein the fifth spacing distance is equal to or smaller than the third spacing distance. The method according to claim 1,
Wherein the contact portion is formed at a point where the imaginary line extending the permanent magnet and the frame meet. The method according to claim 1,
Wherein the permanent magnets are made of a ferrite material.

Images