KR102228858B1 - Linear compressor - Google Patents

Abstract

The present invention includes a compressor body comprising a linear motor for forming a motion of a mover, and compressing a refrigerant by a reciprocating motion of a piston coupled to the mover; And a support member for absorbing vibration generated from the compressor body, wherein the support member comprises: a guide part installed on one side of the compressor body; And a bushing part which is inserted in the guide part so as to support a load in the direction of gravity of the compressor body, wherein each configuration of the compressor body can be aligned on the same line.

Description

Linear compressor {LINEAR COMPRESSOR}

The present invention relates to a linear compressor that compresses a refrigerant by a linear reciprocating motion of a vibrating body.

Compressors can be classified into a rotary type and a reciprocating type according to the method of compressing the refrigerant. It refers to a device configured to compress working fluid such as air or refrigerant by receiving power from a power generating device such as a motor or a turbine. Compressors are widely applied to the entire industry or home appliances, in particular, the steam compression chamber refrigeration cycle (hereinafter referred to as'refrigeration cycle').

These types of compressors include a reciprocating compressor in which a compression chamber is formed between a piston and a cylinder and the piston compresses the refrigerant by linearly reciprocating motion, a rotary compressor that compresses fluid by a roller eccentrically rotated inside the cylinder, and as long as it is made of a spiral. There is a scroll compressor that compresses fluid by rotating a pair of scrolls.

Recently, among reciprocating compressors, the use of a linear compressor using a linear reciprocating motion without a crankshaft has been gradually increasing. The linear compressor has the advantage of having a relatively simple structure and improving the efficiency of the compressor because there is little mechanical loss associated with converting rotational motion to linear reciprocating motion.

In the linear compressor, a cylinder is positioned inside a casing forming a closed space to form a compression chamber, and a piston covering the compression chamber is configured to reciprocate inside the cylinder. In a linear compressor, fluid in the closed space is sucked into the compression chamber while the piston is positioned at the bottom dead center (BDC), and the fluid in the compression chamber is sucked into the compression chamber when the piston is positioned at the top dead center (TDC). The process of being compressed and discharged is repeated.

A compression unit and a driving unit are respectively installed inside the linear compressor, and the compression unit performs a process of compressing and discharging the refrigerant while performing a resonant motion by a resonance spring through the movement generated by the driving unit.

In a linear compressor, the piston reciprocates at high speed inside the cylinder by a resonance spring, inhaling the refrigerant into the casing through a suction pipe, and then being discharged from the compression space through the forward motion of the piston and moving to the condenser through the discharge pipe. A series of processes is repeatedly performed.

1 is a view of Patent Document 1 (Korean Patent Laid-Open Publication No. KR10-2016-0024217) showing the interior of a conventional linear compressor.

The conventional linear compressor 10 includes leaf springs 61 and 62 in a configuration so that internal components of the compressor installed in the circular casing 11 are supported by the casing 11. The first leaf spring 61 and the second leaf spring 62 are respectively installed at both ends of the internal components of the compressor to support the internal components of the compressor and absorb the shock caused by the movement of the drive unit 30.

The leaf springs 61 and 62 coupled to the inside of the compressor require a separate support structure 65 to be fixed to the inside of the casing 11, which complicates assembly of the compressor and increases the material cost. It causes a problem that a separate space is required inside the compressor.

In addition, due to the weight of the internal components of the compressor, the internal components of the compressor supported by the leaf springs 61 and 62 are inclined in the direction of gravity, and the casing 11 and the internal components of the compressor are not aligned at regular intervals, thereby driving the compressor. There is a risk of conflict with each other. In addition, since a separate stopper, such as a leaf spring, must be installed inside the compressor, which is located horizontally, to prevent vibration in the vertical direction, it is a cause of further complicating the structure of the compressor.

Korean Patent Application Publication No. KR10-2016-0024217

An object of the present invention is to provide a structure of a linear compressor capable of stable driving while maintaining a constant distance between a casing and a compressor body installed in an inner space of the casing.

Another object of the present invention is to provide a structure of a linear compressor having a compact structure by removing a plate spring and a fixing member for supporting it.

Another object of the present invention is to provide a structure of a linear compressor that can be aligned while maintaining a certain distance between a casing and a compressor body by preventing the compressor body from tilting in the direction of gravity.

Another object of the present invention is to provide a linear compressor having a structure capable of replacing a casing forming a closed space with an open support bracket.

In order to achieve the object of the present invention, a linear compressor according to the present invention includes: a compressor body comprising a linear motor for forming a motion of a mover, and compressing a refrigerant by a reciprocating motion of a piston coupled to the mover; And a support member for absorbing vibration generated from the compressor body, wherein the support member guides the movement of the compressor body, and is provided on one side of the compressor body and an inner surface of a casing in which the compressor body is accommodated. A guide part that becomes; And a bushing part installed on the inner side of the casing and one side of the compressor body so as to correspond to each of the guide parts, the guide part being slidably inserted to support the load in the direction of gravity of the compressor body, and the bushing part And an elastic portion installed between the guide portion, wherein the elastic portion is installed to be fitted to an outer circumferential surface of the bushing portion, and provides an elastic force such that a length inserted along the bushing portion of the guide portion is limited, and in the compressor body, A plurality of discharge covers are installed to overlap each other to form a discharge space, and a discharge pipe communicating with the discharge cover to discharge the refrigerant discharged from the discharge space is installed in the compressor body, and the guide part is a part of the discharge cover. A first guide portion installed on a side thereof, and a second guide portion disposed on an opposite side of the first guide with the compressor body interposed therebetween, and a second guide portion installed on an inner surface of the casing, wherein the bushing portion includes the first guide portion And a first bushing part installed on the inner side of the casing to accommodate the first guide part to correspond to, and a second bushing part installed on one side of the compressor body so that the second guide part is inserted, and the first The guide part may form a buffer space for absorbing shocks inside the first bushing part while moving toward the first bushing part.

In this case, an insertion hole is formed in the center of the first bushing part and the second bushing part, respectively, the first guide part is inserted toward the insertion hole of the first bushing part, and the second guide part is inserted into the second bushing part. It may be formed to be inserted toward the hole.

In addition, a refrigerant flow path for moving the refrigerant is formed in the center of the second guide part, and the refrigerant flow path is installed on the rear side of the casing and communicates with a suction pipe for sucking the refrigerant, Movement passage can be formed.

In addition, the refrigerant flow path may be formed integrally with the suction pipe, and the suction pipe may be inserted into the second bushing.

In addition, metal coatings may be formed on inner circumferential surfaces of the insertion holes formed in the centers of the first and second bushings, respectively.

According to an example of the present invention, a compressor body comprising a linear motor for forming a motion of a mover, and compressing a refrigerant by a reciprocating motion of a piston coupled to the mover; A support member for absorbing vibration generated from the compressor body; And a support bracket including a bottom member and a column member installed in a direction intersecting with the bottom member on both sides of the bottom member to support the compressor body, wherein the support member includes the column member and the compressor A guide portion supporting the main body, wherein the support member guides the movement of the compressor main body, and is provided on one side of the compressor main body and an inner side surface of the column member, respectively; Bushings respectively installed on one side of the compressor body and one side of the inner side of the column member so as to correspond to each of the guides, and the guides are slidably inserted to support the load in the direction of gravity of the compressor body; And an elastic portion installed between the bushing portion and the guide portion, wherein the elastic portion is installed to be fitted to an outer circumferential surface of the bushing portion, and provides an elastic force such that a length inserted along the bushing portion of the guide portion is limited, and the In the compressor body, a plurality of discharge covers are installed to overlap each other to form a discharge space, and a discharge pipe communicating with the discharge cover on one side to discharge the refrigerant discharged from the discharge space is installed, and the guide part includes the discharge A first guide part installed on one side of the cover, and a second guide part disposed on the opposite side of the first guide with the compressor body interposed therebetween, and a second guide part installed on an inner surface of the column member, and the bushing part comprises: A first bushing part installed on the inner surface of the column member to correspond to the first guide part to receive the first guide part, and a second bushing part installed on one side of the compressor body so that the second guide part is inserted. In addition, while the first guide part moves toward the first bushing part, a buffer space for absorbing shock may be formed inside the first bushing part.

Linear compressors having the above structure can maintain a certain distance between the casing and the compressor body located inside the casing through the configuration of a support member consisting of a guide part and a bushing part, and the compressor body is evenly aligned inside the casing. As a result, it is possible to limit the occurrence of friction or impact even when the compressor is driven. In addition, through the support member, a separate support structure is not required inside the compressor, so it has a relatively simple structure, and the material cost required to manufacture the compressor can be reduced.

In addition, through the guide part and the bushing part, it is possible to support the main body of the compressor installed inside the casing, the shock can be sufficiently absorbed by the driving of the compressor, and the internal space of the compressor can be easily secured.

In addition, the guide portion is inserted into the insertion hole of the bushing portion to enable vertical support of the compressor body, and the elastic portion provides an elastic force so that the insertion length of the guide portion is adjusted, so that the left-right movement of the structure installed inside the casing can be controlled. Accordingly, alignment between the casing and the internal configuration of the compressor is possible.

Further, in the linear compressor, since the internal components can be fixed through the support member, it is possible to replace the casing forming the closed space with the support bracket.

1 is a cross-sectional view showing a state of a conventional linear compressor.
Figure 2 is a cross-sectional view showing the interior of the linear compressor according to the invention.
3 is a perspective view showing a state of a support member included in the linear compressor of FIG. 2.
4 is a cross-sectional view showing another embodiment of the linear compressor according to the present invention.
5 is a perspective view showing a state of a support member included in the linear compressor of FIG. 4.
6 is a cross-sectional view of a linear compressor showing still another embodiment of the present invention.
7 is an enlarged view of an enlarged view of the support member of FIG. 6.
8 is a cross-sectional view showing a state of a linear compressor according to another embodiment of the present invention.

Hereinafter, a linear compressor according to the present invention will be described in more detail with reference to the drawings.

In the present specification, expressions in the singular include plural expressions unless the context clearly indicates otherwise.

In describing the embodiments disclosed in the present specification, when it is determined that a detailed description of related known technologies may obscure the subject matter of the embodiments disclosed in the present specification, a detailed description thereof will be omitted.

The accompanying drawings are only for making it easier to understand the embodiments disclosed in the present specification, and the technical idea disclosed in the present specification is not limited by the accompanying drawings, and all changes and equivalents included in the spirit and scope of the present invention It should be understood to include water or substitutes.

1 is a diagram showing a state of a conventional linear compressor 10.

The linear compressor 10 includes a casing 11 and a compressor body. Here, the compressor main body includes the frame 20, the drive unit 30, and the compression unit 40, which means that it is installed in the inner space of the casing 11.

A frame 20 is installed in the inner space of the casing 11 constituting a closed space. The driving unit 30 is coupled to and supported by the frame 20, and a compression unit 40 for sucking and compressing and discharging the refrigerant is coupled to the driving unit 30. The compression unit 40 is supported by being coupled to the frame 20 together with the driving unit 30.

The casing 11 has a shell 11a formed in a cylindrical shape with an opening at both ends thereof in a substantially transverse direction, a first shell cover 11b coupled to the rear side of the shell 11a, and a second shell cover 11b coupled to the front side. It consists of a shell cover (11c). The casing 11 is positioned to lie in the transverse direction, and the first shell cover 11b is on the right side of the shell 11a, and the second shell cover 11c is on the left side of the shell 11a. I can. In addition, the first shell cover 11b and the second shell cover 11c may form part of the shell 11a.

The frame 20 may be supported by being connected to the other end of a support spring positioned so that one end is fixed to the casing 11. As shown in Figure 1, the conventional support spring is generally made of leaf springs (61, 62).

The drive unit 30 may generate a reciprocating motion of the linear compressor 10 and may include stators 31 and 32 and a mover 33. The stators 31 and 32 may be coupled to the frame 20. The stators 31 and 32 include an outer stator 31 disposed to surround the compression unit 40, and an inner stator 32 spaced apart from the outer stator 31 to surround the compression unit 40. . A mover 33 may be positioned between the outer stator 31 and the inner stator 32.

The outer stator 31 may be equipped with a winding coil, and the mover 33 may have a permanent magnet. When a current is applied to the driving unit 30, a flux may be formed in the stator 31 by the winding coil, and the magnetic flux formed by the application of the current and the magnetic flux formed by the permanent magnet may be moved. The movement of (33) can be formed.

The compression unit 40 serves to suction, compress and discharge the refrigerant in the suction space. The compression unit 40 includes a cylinder 41 and a piston 42. The cylinder 41 may be supported by the frame 20 to form a compression chamber P. The cylinder 41 may be formed in a cylindrical shape with one end open, and a discharge valve (not shown) and a discharge cover 45 are mounted at the other end of the cylinder 41 to accommodate the compressed refrigerant.

In addition, the linear compressor 10 includes resonance springs 39a and 39b in a configuration. The resonance springs 39 and 39b amplify vibrations implemented by the reciprocating motion of the mover 33 and the piston 42, thereby effectively compressing the refrigerant. The spring support member 38 is coupled to the connecting member connecting the mover 33 and the piston 42 to be integrally reciprocated.

The internal components of the linear compressor 10 are supported by leaf springs 61 and 62 installed at both ends of the casing 11. The leaf springs 61 and 62 are composed of a first leaf spring 15a and a second leaf spring 15b, and the piston 14b located inside the cylinder 14a while supporting the internal parts of the compressor is reciprocated. It plays a role of absorbing the shock that occurs accordingly.

However, since the supporting structure 65 for fixing the leaf spring 15 to the inside of the casing 11 is separately required, and separate fixing members (stoppers 18, 19) are required due to the drive of the compressor, the internal structure of the compressor Is complicated, and sagging occurs due to the load of the internal components supported by the leaf springs 15 and 16, and there is a concern that it becomes difficult to align the casing 11 and the internal components at a constant interval.

FIG. 2 is a view of a linear compressor 100 including a support member 160, and FIG. 3 is a perspective view illustrating a support member 160 for supporting a compressor body installed inside the casing 110. As shown in FIG.

The linear compressor 100 according to the present invention comprises a casing 110, a frame 120, a driving unit 130, a compression unit 140, and a resonance spring 139, and the interior of the casing 110 Each of the components positioned in the casing 110 has a structure supported by support members 160 positioned on both sides of the casing 110. The compressor body is a concept including each component installed inside the casing 110, and includes a casing 110, a frame 120, a driving unit 130, a compression unit 140, and a resonance spring 139. do.

A frame 120 is installed in the inner space 101 of the casing 110 constituting the closed space of the linear compressor 100. A driving unit 130 is coupled to the frame 120 and supported, and a compression unit 140 for sucking and compressing and discharging the refrigerant is coupled to the driving unit 130. The compression unit 140 is supported by being coupled to the frame 120 together with the driving unit 130.

The casing 110 has a shell 111 formed in an elongated cylindrical shape with an opening at both ends thereof, a first shell cover 112 coupled to the rear side of the shell 111, and a second shell cover 112 coupled to the front side. It consists of a shell cover (113). As shown in FIG. 2, the first shell cover 112 may be coupled to the right side of the shell 111 and the second shell cover 113 to the left side of the shell 111. In addition, the first shell cover 112 and the second shell cover 113 may form part of the shell 111.

Depending on the size of the driving unit 130, the inner diameter of the casing 110 may be variously formed, but the linear compressor 100 according to the present embodiment excludes oil bearings and applies gas bearings to the inside of the casing 110. It is also possible to form the space 101 in an oilless type that does not need to be filled with oil, so that the inner diameter of the casing 110 is as small as possible so as to have only a gap that is not in contact with the inner circumferential surface of the casing 110.

The first shell cover 112 is coupled to the rear side of the casing 110, and a suction port 114 is formed in the first shell cover 112, and a suction pipe SP is inserted and coupled thereto.

A discharge port (not shown) for discharging the refrigerant from the discharge space 102 to the outside may be formed in the second shell cover 113, and a discharge pipe DP may be connected to the outside of the discharge port (not shown).

The driving unit 130 may generate a reciprocating motion of the linear compressor 100 and may include stators 131 and 132 and a mover 133. The stators 131 and 132 may be coupled to the frame 120. The stator 131 may include an outer stator 131 disposed to surround the compression unit 140 and an inner stator 132 spaced apart from the outer stator 131 to surround the compression unit 140. . A mover 133 may be positioned between the outer stator 131 and the inner stator 132.

The outer stator 131 may be equipped with a winding coil, and the mover 133 may have a permanent magnet. When a current is applied to the driving unit 130, a flux may be formed in the stator 131 by the winding coil, and the magnetic flux formed by the application of the current and the magnetic flux formed by the permanent magnet are interacted with each other. Movement of the mover 133 may be formed.

The compression unit 140 is configured to suck, compress, and discharge the refrigerant in the internal space 101. The compression unit 140 includes a cylinder 141 and a piston 142. The cylinder 141 may be supported by the frame 120 to form a compression chamber (P). The cylinder 141 may have a cylindrical shape with one end open, and a discharge valve (not shown) and a discharge cover 145 may be mounted at the other end. The plurality of discharge covers 145 are installed to overlap each other, and a plurality of discharge spaces can be formed.

Inside the casing 110, a discharge pipe DP extending so as to communicate the discharge port 115 and the discharge space 102 with each other may be installed.

The piston 142 is inserted into an open end of the cylinder 141 to seal the compression chamber P. The piston 142 is connected to the mover 133 described above and may reciprocate together with the mover 133. The inner stator 132 and the cylinder 141 may be positioned between the mover 133 and the piston 142, and the mover 133 and the piston 142 may bypass the cylinder 141 and the inner stator 132. They may be coupled to each other by separate connecting members formed.

The piston 142 is formed with a suction pipe SP that seals the compression chamber P and penetrates one end. In this embodiment, the refrigerant in the internal space 101 flows through the internal space of the piston 142 and can be sucked into the compression chamber P between the piston 142 and the cylinder 141.

The linear compressor 100 according to the present invention may further include a resonance spring 139. The resonance spring 139 amplifies the vibration implemented by the reciprocating motion of the mover 133 and the piston 142, and serves to effectively compress the refrigerant. A spring support member 138 is coupled to a connecting member (not shown) connecting the mover 133 and the piston 142 so that the reciprocating motion can be performed integrally.

One end of the resonance spring 139 may be fixed to the spring support member 138, and the other end of the resonance spring 139 may be fixedly coupled to the stator cover 137 or the cover member 134. In addition, as shown in Figure 2, the resonance spring 160, with the spring support member 146 interposed therebetween, a plurality of each may be located on both sides, the resonance spring 139 is one side of the stator cover 137 And a first spring 139a each supporting one surface of the spring support member 138, and a second spring 162 supporting between the other surface of the spring support member 138 and the cover member 148. .

The first spring 139a and the second spring 139b may be formed such that the central portion is formed on the same line, and may be disposed at regular intervals with respect to the central portion of the piston 142. For example, the first spring 139a and the second spring 139b may be disposed at intervals of 120 degrees with respect to the center of the piston 142.

The linear compressor 100 according to the present invention may be configured to include a support member 160.

The support member 160 is installed at both ends of the inner surface of the casing 110 and coupled to each other to support the entire load of the driving unit 130, the compression unit 140, and the resonance spring 139 formed integrally. The support member 160 serves to ensure that the compressor body located inside the casing 110 is positioned at a certain height from the bottom of the casing, and absorbs the shock formed by the movement of the driving unit 130. .

As shown in FIG. 3, the support member 160 includes a bushing part 161 and a guide part 163 in a configuration.

The bushing part 161 is made to have a cylindrical shape such that both ends are opened, and has an insertion hole 164a formed to pass through the center. When the guide part 163 is inserted toward the bushing part 161, the insertion hole 164a of the bushing part 161 and the guide part 163 are in contact with each other and move relative to each other, so that the bushing part 161 ) And at least one of the guide part 163 may be made of a plastic material having a lubricating property.

When the guide part 163 is inserted toward the bushing part 161, it is inserted into the insertion hole of the bushing part 161 as much as the protruding length of the guide part 163, so that the linear compressor 100 according to the present invention is a support member Since the internal components of the compressor are supported through 160, there is an advantage of effectively preventing not only the vertical movement of the compressor, but also the vibration caused by the horizontal movement of the compressor without a separate stoppper. do.

It is preferable that the inner diameter of the insertion hole 164a is larger than the outer diameter of the guide portion 163 so that the guide portion 163 is inserted into the insertion hole 164a and slides. In addition, the insertion hole 164a is made to be in contact with the outer surface of the guide part 163, and a metal coating may be formed on the inner circumferential surface of the insertion hole 164a.

The bushing part 161 is a first bushing part 161a installed on the front inner surface of the casing 110, and a first bushing part 161a positioned to face the first bushing part 161a with an internal configuration of the casing 110 therebetween. It includes two bushings 161b in a configuration. The second bushing part 161b may be installed at the rear end of the resonance springs 139a and 139b. One end of the resonant spring may be supported on one surface of the cover member 134, and one surface of the second bushing 161b may be coupled to the other surface of the cover member 134.

The first bushing part 161a may be installed on the inner side of the second shell cover 113, and the second bushing part 161b is installed at the rear end of the resonance springs 139a and 139b, so that the cover member 134 ) May be installed to face the first shell cover 112.

The guide part 163 is formed to protrude toward each of the bushing parts 161a and 162a from the front part of the driving unit 130 and the rear part of the resonance springs 139a and 139b, and the respective bushing parts 161a and 162a ) Is made to slide along the insertion holes (164a, 164b).

The guide part 163 is inserted and supported in the insertion holes 164a, 164b of each bushing part 161a, 162a, so the compression unit 140, the driving unit 130, and the resonance combined with the guide part 163 It becomes possible to support the springs (139a, 139b)

The guide part 163 of the first guide part 163a and the casing 110 fixedly installed on the discharge cover 104 installed at the front end of the driving unit 130 so as to correspond to the first bushing part 161a. It includes a second guide portion 163b installed on the rear inner surface to be inserted into the second bushing portion 162a.

The first guide part 163a is inserted into the insertion hole 164a formed in the first bushing part 161a, and the second guide part 163b is an insertion hole 164b formed in the second bushing part 162a. It is inserted into, it is possible to stably support the compressor body installed inside the casing (110). In this case, compared to supporting the compressor body installed inside the casing 110 in the same configuration as the leaf springs installed at both ends, the sagging phenomenon is prevented, so that the gap between the casing 110 and the internal components is kept constant. There is an advantage to be able to.

In the linear compressor 100 according to the present invention, a refrigerant flow path 165 is formed in the center of the second guide part 163b to form a movement path of the refrigerant flowing through the suction pipe SP. In this case, both ends of the second guide part 163b are made to be opened, one open end is fixedly installed on the inner side of the first shell cover 112, and the other end is the second bushing part 161b. It is made to be accommodated in the inside of, so that the refrigerant can move toward the compression chamber (P).

4 is a cross-sectional view of a linear compressor 200 including the support member 260, and FIG. 5 is a perspective view illustrating a support member 260 according to another embodiment of the present invention.

Since the linear compressor 200 according to the present embodiment is configured to include the configuration of the linear compressor 100 described in FIGS. 2 and 3, a description thereof will be omitted in the overlapping range.

The driving process of the linear compressor 200 will be described. When a current is applied to the driving unit 230, a flux is formed in the stator 231, and the mover 233 having a permanent magnet is formed in a straight line by electromagnetic force generated by the magnetic flux formed in the stator 231. A reciprocating motion of the piston 242 connected to the mover 233 is performed by performing a reciprocating motion.

The piston 242 reciprocating within the cylinder 241 repeats the movement of increasing and decreasing the volume of the compression chamber P. When the piston 242 moves while increasing the volume of the compression chamber P, the pressure inside the compression chamber P decreases. Accordingly, a suction valve (not shown) mounted on the piston 242 is opened, and the refrigerant remaining in the suction space 201 may be sucked into the compression chamber P. This suction stroke proceeds until the piston 242 increases the volume of the compression chamber P to the maximum and is positioned at the bottom dead center (BDC).

The piston 242 reaching the bottom dead center performs a compression stroke while reducing the volume of the compression chamber P. The compression stroke is performed while the piston 242 is moved to a top dead center (TDC) where the volume of the compression chamber P is reduced to a minimum. During the compression stroke, the pressure inside the compression chamber P is increased so that the sucked refrigerant may be compressed. When the pressure in the compression chamber P reaches a preset pressure, a discharge valve (not shown) mounted on the cylinder 241 is opened to discharge the refrigerant into the discharge space 204.

In addition, during the reciprocating motion of the piston 242, the resonance spring 160 may be compressed and stretched according to the frequency of the piston 242 to cause a resonance phenomenon, and an efficient compressor operation compared to the input electric energy is performed.

In the driving process of the linear compressor 200, vibration is generated according to the movement of the driving unit 230, so when the components located inside the casing 210 are not aligned in a line on the same line, the inner surface of the casing There is a risk of a collision or a phenomenon in which the compressor may not operate stably.

Accordingly, the linear compressor 200 according to the present invention aligns each of the components constituting the compressor body installed inside the casing 210 through the support member 260 so that the inside of the casing 210 and the casing 210 It is possible to limit the occurrence of friction or impact between the casing 210 when the compressor is driven by maintaining a constant angle between the positioned components.

As shown in FIG. 5, the support member 260 may be formed to include a bushing part 261, a guide part 263, and an elastic part 262.

The support member 260 may be installed at both ends of the inner surface of the casing 210 to support the entire load of the driving unit 230, the compression unit 240, and the resonance spring 239 formed integrally by being combined with each other. The support member 260 serves to position the compressor body located inside the casing 210 at a certain height from the bottom surface of the casing 210, and absorbs the shock formed by the movement of the driving unit 230. I can.

The bushing part 261 is made to have a cylindrical shape such that both ends are opened, and includes an insertion hole 264a formed to penetrate the center. Since the guide portion 263 is inserted and slides toward the insertion hole 264a, the inner diameter of the insertion hole 264a is preferably made to be larger than the outer diameter of the guide portion 263.

However, as described above, since the refrigerant flow path 265 is formed in the center of the second guide part 263 to form a moving path for the refrigerant introduced along the suction pipe SP, it moves toward the compression chamber P. In order to prevent leakage of the refrigerant, it is preferable that the inner diameter of the insertion hole 264b is made of a small difference in size between the outer diameter of the guide portion 263b.

The bushing part 261 is a first bushing part 261a installed on the front inner surface of the casing 210, and a first bushing part 261a disposed to face the first bushing part 261a with an internal configuration of the casing 210 therebetween. It includes two bushings 261b in a configuration, and the second bushings 261b may be installed at the rear ends of the resonance springs 239a and 239b.

The support member 260 may be formed to further include an elastic portion 262. The elastic part 262 is installed between the bushing part 261 and the guide part 263 to provide an elastic force between the guide part 263 and the bushing part 261, and the guide part 263 is a bushing It is possible to adjust the length to be inserted along the insertion hole (264a) of the portion 261.

The elastic part 262 is installed to fit into the outer circumferential surface of the bushing part 261, and formed in a radial direction on one end of the guide part 263 and a flange (not shown) formed on the front end surface of the bushing part 261 It may be made to be supported by each of the flanges (not shown).

Accordingly, the elastic part 262 can absorb the impact force generated while the guide part 263 moves along the bushing part 261.

The elastic portion 262 may be formed of any one of a coil spring formed to wind a compressed coil and a plate spring formed in a circular plate shape. In addition, the elastic portion 262 may be made of a wave spring providing high rigidity in the stretch direction.

6 is a cross-sectional view of a linear compressor 300 showing another embodiment of the present invention, and FIG. 7 is an enlarged enlarged view of the support members 360a and 360b installed on the first shell cover 312 .

The linear compressor 300 according to the present embodiment comprises a casing 310, a frame 320, a driving unit 330, a compression unit 340, and a resonance spring 339 in a configuration, and the casing 310 It is made to be supported through support members (360a, 360b) located on both sides of the internal components located inside. Descriptions related to this are the same as those described.

The linear compressor 300 according to the present embodiment is made to include support members 360a and 360b, and the support members 360a and 360b constitute bushing portions 361a and 361b and guide portions 363a and 363b. Include as.

In addition, a support member 360a is installed on one side of the compressor body, and a plate-shaped plate spring (not shown) having an elastic force is installed on the other side, so that it is possible to absorb vibrations of the compressor body.

The bushing portions 361a and 361b are formed to have a cylindrical shape such that both ends are opened, and have an insertion hole 364a formed to pass through the central portion. It is preferable that the inner diameter of the insertion hole 364a is larger than the outer diameter of the guide portion so that the guide portions 363a and 363b are inserted and slid into the insertion hole 364a.

The bushing part 361 is a first bushing part 361a installed on the front inner surface of the casing 310, and a first bushing part 361a disposed to face the first bushing part 361a with an internal configuration of the casing 310 therebetween. It includes two bushing portions 361b in a configuration. The second bushing part 361b may be installed at the rear ends of the resonance springs 339a and 339b. One end of the resonant spring may be supported on one surface of the cover member 334, and one surface of the second bushing 361b may be coupled to the other surface of the cover member 334.

The first bushing part 361a may be installed on the inner side of the second shell cover 313, and the second bushing part 361b is installed at the rear ends of the resonance springs 339a and 339b, so that the cover member 334 ) May be installed to face the first shell cover 312.

The guide portions 363a and 363b are formed to protrude toward the respective bushing portions 361a and 362a from the front portion of the driving unit 330 and the rear portions of the resonance springs 339a and 339b, and the respective bushing portions 361a , 362a) is made to slide along the insertion hole.

Since the guide portions 363a and 363b are inserted and supported in the insertion holes of each bushing portion 361a and 362a, the compression unit 340, the driving unit 330 and the resonance spring coupled with the guide portions 363a and 363b (339a, 339b) will be able to support the whole

The guide portions 363a and 363b are fixed to the discharge cover 304 installed at the front end of the driving unit 330 so as to correspond to the first bushing portion 361a. ) And a second guide part 363b installed on the rear inner surface of the second bushing part 362a to be inserted into the second bushing part 362a.

The first guide part 363a is inserted into the insertion hole formed in the first bushing part 361a, and the second guide part 363b is inserted into the insertion hole 364b formed in the second bushing part 362b. , It is possible to stably support the compressor body installed inside the casing 310.

The second guide part 363b may include a refrigerant flow path formed to pass through the center thereof, and the refrigerant flow path may form a movement path of the refrigerant introduced along the suction pipe SP. In this case, the refrigerant flow path may be installed on the rear surface of the casing 310 and formed integrally with a suction pipe for sucking the refrigerant.

That is, the second guide portion 363b is inserted into the second bushing portion 362b, and the second guide portion 363b may be replaced with a suction pipe SP for inhaling the refrigerant.

8 is a cross-sectional view showing a state of a linear compressor 400 according to another embodiment of the present invention.

The linear compressor 400 has a structure in which the frame 420, the driving unit 430, and the compression unit 440 are fixed through the support brackets 410a, 410b, and 410c. In addition, the linear compressor 400 may include support members 460a and 460b in a configuration.

The linear compressor 400 according to the present embodiment has a structure in which components of the compressor can be supported through the support members 460a and 460b.

The support members 460a and 460b support the entire load of the driving unit 330, the compression unit 340, and the resonance spring 339, as described above. The support members 460a, 460b are installed on the support brackets 410a, 410b, 410c, and serve to position each of the components constituting the main body of the compressor as a floor member at a certain height. It becomes possible to absorb the impact formed by it.

The support members 460a and 460b include bushings 461a and 461b and guides 463a and 463b, and the guides 463a and 463b are inserted into the bushings 461a and 461b to support the components of the compressor. You can do it. A detailed description of this will be replaced with the description of FIGS. 2 to 7.

The linear compressor 400 according to the present embodiment may include support brackets 410a, 410b, and 410c instead of a sealed casing, and the configuration of the compressor may be installed by the support members 460a and 460b.

The support member 460 includes a bushing part 461, a guide part 463, and an elastic part 462 in the same manner as described above.

The second guide part 463b may be inserted into the insertion hole 464b formed in the center of the bushing part 461b, and the moving passage 466 may be inserted into the other end of the insertion hole 464b.

The refrigerant flowing into the suction pipe SP may move along the refrigerant passage 465 formed in the guide part 463 and then move to the compression chamber through the muffler (not shown) along the moving passage 466.

The outer diameter of the guide portion 463 is made to be substantially the same as the size of the inner diameter of the insertion hole of the bushing portion 461. Since the second guide part 463b is inserted into the insertion hole 464b formed in the center of the bushing part 461b, the refrigerant flowing through the suction pipe SP does not leak and can move along the moving flow path 466. .

Since the moving passage 466 is installed at one side of the other opening of the insertion hole 464b of the second bushing part 461b, the refrigerant moving along the refrigerant passage 465 of the guide part 463 does not leak, It is possible to move to the compression chamber through the moving passage 464.

Each of the components of the linear compressor 400 according to the present invention may be fixedly installed to the support brackets 410a, 410b, 410c through the support members 460a, 460b, and the refrigerant flowing along the suction pipe SP does not leak. Without moving to the compression chamber (P), it can be discharged after being compressed.

The support brackets 410a, 410b, 410c may be formed of a bottom member 410c and column members 410a, 410b. The bottom member 410c is installed on the bottom surface from the bottom of the compressor, and each column member 410a, 410b is installed on both sides of the bottom member 410c, and the support members 460a, 460b are column members 410a, It is installed on both sides of the 410b), so that the combination of the driving unit 430, the compression unit 440, and the resonance springs 439a and 439b can be fixed.

The driving unit 430 is coupled to and supported by the frame 420, and a compression unit 440 for sucking and compressing and discharging the refrigerant is coupled to the driving unit 430. The compression unit 440 is coupled to the frame 420 together with the driving unit 430 to be integrally supported.

What has been described above are only examples for implementing the linear compressor according to the present invention, and the present invention is not limited to the above embodiments, and does not depart from the gist of the present invention as claimed in the claims below. Within the scope, anyone of ordinary skill in the field to which the present invention pertains will have the technical idea of the present invention to the extent that various modifications can be implemented.

100, 200, 300, 400: linear compressor
110, 210, 310, 410: casing
120, 220, 320, 420: frame
130, 230, 330, 430: drive unit
140, 240, 340, 440: compression unit
160, 260, 360, 460: support member
161, 261, 361, 461: bushing part
262, 362, 462: elastic portion
163, 263, 363, 463: guide part

Claims (6)

A compressor body having a linear motor for forming a motion of a mover, and compressing a refrigerant by a reciprocating motion of a piston coupled to the mover; And
It includes a support member for absorbing the vibration generated from the compressor body,
The support member,
A guide unit that guides the movement of the compressor body and is provided on one side of the compressor body and an inner side surface of a casing in which the compressor body is accommodated;
A bushing portion installed on an inner side of the casing and one side of the compressor body so as to correspond to each of the guide portions so as to slide the guide portion to support the load in the direction of gravity of the compressor body; And
It includes an elastic portion installed between the bushing portion and the guide portion,
The elastic portion is installed so as to be fitted to the outer circumferential surface of the bushing portion, and provides an elastic force such that a length inserted along the bushing portion of the guide portion is limited,
In the compressor body, a plurality of discharge covers are installed so as to overlap each other to form a discharge space, and a discharge pipe communicating with the discharge cover on one side to discharge the refrigerant discharged from the discharge space is installed,
The guide part has a first guide part installed on one side of the discharge cover, and a second guide part located on the opposite side of the first guide with the compressor body interposed therebetween and installed on the inner side of the first shell cover of the casing Including,
The bushing part includes a first bushing part installed on the inner side of the second shell cover of the casing so as to correspond to the first guide part to receive the first guide part, and one side of the compressor body so that the second guide part is inserted. It includes a second bushing installed in the,
The first guide part, while moving toward the first bushing part, to form a buffer space for shock absorption inside the first bushing part. The method of claim 1,
Insertion holes are formed in the centers of the first and second bushings, respectively,
The first guide portion is inserted toward the insertion hole of the first bushing portion, and the second guide portion is formed to be inserted toward the insertion hole of the second bushing portion. The method of claim 1,
A refrigerant flow path for moving the refrigerant is formed in the center of the second guide part,
The refrigerant flow path is installed at a rear portion of the casing and communicates with a suction pipe for sucking the refrigerant to form a passage for the refrigerant introduced along the suction pipe. The method of claim 3,
The refrigerant flow path is formed integrally with the suction pipe,
The suction pipe is a linear compressor, characterized in that configured to be inserted into the second bushing. The method of claim 2,
The linear compressor, characterized in that a metallic coating is formed on an inner circumferential surface of the insertion hole formed in the center of the first bushing part and the second bushing part. A compressor body having a linear motor for forming a motion of a mover, and compressing a refrigerant by a reciprocating motion of a piston coupled to the mover;
A support member for absorbing vibration generated from the compressor body; And
And a support bracket including a bottom member and a column member installed in a direction crossing the bottom member on both sides of the bottom member to support the compressor body,
The support member supports the compressor body together with the column member,
The support member,
A guide portion that guides the movement of the compressor body and is provided on one side of the compressor body and an inner side surface of the column member, respectively;
Bushings respectively installed on one side of the compressor body and one side of the inner side of the column member so as to correspond to each of the guides, so that the guides are slidably inserted to support the load in the direction of gravity of the compressor body; And
It includes an elastic portion installed between the bushing portion and the guide portion,
The elastic portion is installed so as to be fitted to the outer circumferential surface of the bushing portion, and provides an elastic force such that a length inserted along the bushing portion of the guide portion is limited,
In the compressor body, a plurality of discharge covers are installed so as to overlap each other to form a discharge space, and a discharge pipe communicating with the discharge cover on one side to discharge the refrigerant discharged from the discharge space is installed,
The guide portion includes a first guide portion installed on one side of the discharge cover, and a second guide portion disposed on an opposite side of the first guide with the compressor body interposed therebetween and installed on an inner surface of the column member, ,
The bushing part is installed on the inner side of the column member to correspond to the first guide part, the first bushing part receiving the first guide part, and the second guide part being installed on one side of the compressor body to be inserted. It includes a second bushing part,
The linear compressor, wherein the first guide portion moves toward the first bushing portion and forms a buffer space for shock absorption inside the first bushing portion.

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