KR20080050729A - Hermetic type compressor - Google Patents

Abstract

A hermetic compressor is provided to commonly use a cylinder and a frame integrally formed with the cylinder for manufacturing compressors of different piston displacement by simply changing a compression chamber forming element. A hermetic compressor includes a piston(22) reciprocating straightly by driving force of a driving unit, and a cylinder(23) having a compression chamber(23a) for the piston. The cylinder has a body part(50) having a hollow part(51), and a compression chamber forming element(60) inserted into the hollow part for forming the compression chamber by an inner diameter portion thereof, wherein piston displacement is variable according to the size of the inner diameter of the compression chamber forming element.

Description

Hermetic Compressor {HERMETIC TYPE COMPRESSOR}

1 is a cross-sectional view showing the overall structure of a hermetic compressor according to an embodiment of the present invention.

FIG. 2 is an enlarged cross-sectional view of the cylinder-side structure of FIG. 1.

Figure 3 is a perspective view showing the cylinder-side structure in the hermetic compressor according to an embodiment of the present invention, showing a state in which the compression chamber forming member is separated from the body of the cylinder.

Figure 4 is a perspective view showing a cylinder side structure in the hermetic compressor according to the present invention, showing a state in which the compression chamber forming member according to another embodiment is separated from the body of the cylinder.

Explanation of symbols on the main parts of the drawings

22: piston 23: cylinder

23a: compression chamber 30: frame

50: body 51: hollow part

60: compression chamber forming member

The present invention relates to a hermetic compressor, and more particularly, to a hermetic compressor in which a cylinder member having a compression chamber can be used in common even if the displacement is changed.

In general, the hermetic compressor is adopted to compress the refrigerant in a refrigerating cycle of a refrigerator or an air conditioner, and forms an appearance through a sealed container, and on one side and the other side of the sealed container, the refrigerant passed through the evaporator of the refrigeration cycle into the sealed container. The guide suction pipe and the discharge pipe for guiding the refrigerant compressed in the sealed container toward the condenser of the refrigeration cycle are respectively installed.

A compression unit for compressing the refrigerant and a driving unit for providing a compression driving force of the refrigerant are provided in the sealed container, and the compression unit and the driving unit are installed through a frame.

The drive unit includes a stator installed to be fixed to the lower outer portion of the frame, and a rotor installed inside the stator to rotate by electrical interaction with the stator. The driving force of the drive unit is transmitted to the compression unit through the rotating shaft. .

A through part is formed in the center of the frame to rotatably support the rotating shaft for installation of the rotating shaft, and the rotating shaft under the through portion is pressed into the center of the rotating shaft so that the rotating shaft can rotate together when the rotor is rotated.

In addition, one end of the rotating shaft of the upper part of the through-shape forms an eccentric shaft portion which rotates eccentrically. It is provided with a cylinder formed on one side of the upper frame to form a compression chamber to be reciprocated. The cylinder may be formed integrally with the frame, or may be provided to be fastened to the frame in a state of being manufactured separately from the frame.

In addition, the compression unit is for sealing the compression chamber, and provided with a refrigerant suction chamber and a refrigerant discharge chamber, which are partitioned to each other, a cylinder head coupled to one end of the cylinder, and provided between the cylinder and the cylinder head to be sucked or compressed into the compression chamber from the refrigerant suction chamber. And a valve device provided to control the flow of the refrigerant discharged from the chamber to the refrigerant discharge chamber. The refrigerant suction chamber guides the refrigerant guided into the sealed container through the suction tube to the compression chamber, and the refrigerant discharge chamber receives the refrigerant discharged from the compression chamber and guides the discharged refrigerant to the discharge tube.

Through this structure, when the eccentric shaft portion is eccentrically rotated while the rotating shaft rotates according to the driving of the driving unit, the piston connected through the eccentric shaft portion and the connecting rod linearly reciprocates in the compression chamber and between the compression chamber inside and the outside A pressure difference is formed in the air, and the refrigerant guided into the sealed container along the suction pipe through the pressure difference is sucked into the compression chamber via the refrigerant suction chamber and compressed, and the refrigerant compressed in the compression chamber is discharged into the refrigerant discharge chamber. The refrigerant is delivered to the condenser of the refrigeration cycle along the discharge tube to perform the compression of the refrigerant.

On the other hand, in such a hermetic compressor, the displacement which shows the compression capacity of the refrigerant is usually determined according to the linear reciprocating distance of the piston or the size of the compression chamber. In the case of changing the size of the compression chamber, the hermetic compressor According to the displacement of the need arises a number of separate cylinders to be produced.

That is, in the conventional hermetic compressor, when the volume of the compression chamber is increased to increase the displacement or the volume of the compression chamber is formed to be smaller to reduce the displacement, the structure of the cylinder is changed accordingly. In this case, according to the displacement of the hermetic compressor The manufacturing cost of the hermetic compressor is excessively increased because several cylinders having a compression chamber having a volume corresponding thereto are excessively increased. In particular, when the cylinder and the frame are integrally formed as described above, the entire frame in which the cylinder is integrally formed is Depending on the amount of displacement, the need to prepare several will occur.

The present invention is to solve such a problem, it is an object of the present invention to provide a hermetic compressor provided so that the cylinder having a compression chamber can be used in common even if the displacement is changed.

The hermetic compressor according to the present invention for achieving this object is provided with a cylinder having a piston reciprocating linearly by receiving the driving force of the drive unit, and a compression chamber in which the piston is reciprocating linearly therein, the cylinder And a body including a hollow part and a compression chamber forming member provided to be inserted into the hollow part to form the compression chamber through an inner diameter so that the displacement can be varied according to the inner diameter of the compression chamber forming member. do.

And a cylinder head coupled to one end of the cylinder in the forward direction of the piston to seal the compression chamber, and interposed between the cylinder and the cylinder head to control a flow of refrigerant sucked into or discharged from the compression chamber. Further comprising a valve device, characterized in that one end of the compression chamber forming member toward the forward direction of the piston is provided to be supported by the valve device.

In addition, the outer diameter of the compression chamber forming member is formed stepped so that the forward direction of the piston is larger than the reverse direction of the piston to prevent the compression chamber forming member from falling into the reverse direction of the piston, the hollow The inner diameter of the part is formed to correspond to the outer diameter of the compression chamber forming member.

In addition, an insertion protrusion is formed in an outer diameter of the compression chamber forming member so as to prevent the piston forming member from flowing toward the reverse direction of the piston, and an insertion groove is provided in the hollow part inner diameter at a position corresponding thereto. It is characterized by.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the hermetic compressor according to the present embodiment has an appearance through the hermetic container 1 formed by combining the upper container 1a and the lower container 1b with each other.

One side of the sealed container (1) is provided with a suction pipe (1c) for guiding the refrigerant passing through the evaporator of the refrigeration cycle into the sealed container (1), the other side is a refrigerant condenser of the refrigerant in the sealed container (1) Discharge pipes 1d for guiding to each side are provided.

In addition, a compression unit 20 and a driving unit 10 are installed in the sealed container 1. In the present embodiment, the compression unit 20 and the driving unit 10 are connected to each other through the frame 30. Is installed.

First, the drive unit 10 includes a stator 11 installed to be fixed to the lower outer portion of the frame 30 and a rotor installed inside the stator 11 to rotate by electrical interaction with the stator 11. 12), the driving force of the drive unit 10 is transmitted to the compression unit 20 through the rotating shaft (40).

The rotating shaft 40 is rotatably supported by the penetrating portion 31 formed at the center of the frame 30, and the rotating shaft 40 under the penetrating portion 31 is pressed into the center of the rotor 12 and rotated. The rotation shaft 40 is provided to rotate together when the electron 12 rotates, and one end of the rotation shaft 40 on the upper portion of the through part 31 forms an eccentric shaft portion 41 for eccentric rotation.

And the compression unit 20 is connected via the eccentric shaft portion 41 and the connecting rod 21, the piston 22 and the piston 22 is provided to linearly reciprocate during the eccentric rotation of the eccentric shaft portion 41, the piston 22 therein A cylinder 23 formed integrally with the frame 30 is provided on one side of the upper portion of the frame 30 so as to have a compression chamber 23a for linear reciprocating motion.

In addition, the compression unit 20 is for sealing the compression chamber 23a and includes a refrigerant suction chamber 24a and a refrigerant discharge chamber 24b provided to be partitioned with each other so that the cylinder 23 on the forward direction of the piston 22 is provided. A cylinder head 24 coupled to one end and provided between the cylinder 23 and the cylinder head 24 are sucked from the refrigerant suction chamber 24a into the compression chamber 23a or from the compression chamber 23a. The valve device 25 is further provided to interrupt the flow of the refrigerant discharged to 24b).

Here, the refrigerant suction chamber 24a guides the refrigerant guided into the sealed container 1 through the suction pipe 1c to the compression chamber 23a, and the refrigerant discharge chamber 24b is the compression chamber 23a. The refrigerant is compressed and discharged from the delivery is guided to the discharge pipe (1d).

When the eccentric shaft portion 41 is eccentrically rotated while the rotating shaft 40 rotates according to the driving of the driving unit 10 through this structure, the piston connected through the eccentric shaft portion 41 and the connecting rod 21. (22) is linear reciprocating movement in the compression chamber (23a) and a pressure difference is formed between the inside and the outside of the compression chamber (23a), through the pressure difference guided into the closed container (1) along the suction pipe (1c) The refrigerant is sucked into the compression chamber 23a via the refrigerant suction chamber 24a and compressed, and the refrigerant compressed in the compression chamber 23a is discharged into the refrigerant discharge chamber 24b and then discharged 1d. As it is delivered to the condenser of the refrigeration cycle along the compression of the refrigerant.

On the other hand, in the hermetic compressor according to the present embodiment, the cylinder 23 is a body 50 having a hollow portion 51, as shown in Figures 2 and 3, and the hollow of the body 50 The compression chamber forming member 60 is provided to be inserted into the unit 51, and the compression chamber 23a is formed through the inner diameter of the compression chamber forming member 60.

Thus, the cylinder 23 is comprised through the body 50 which has the hollow part 51, and the compression chamber forming member 60 inserted in the said hollow part 51, The said compression chamber 23a is this pressure | pressure_type | compression_pressure. The structure that is formed through the inner diameter of the shaft forming member 60 has a frame 30 in which the cylinder 23 and the cylinder 23 having the compression chamber 23a are integrally formed in the manufacture of a hermetic compressor having different displacements. In order to reduce the cost of manufacturing a large number of hermetic compressors with different displacements.

That is, in the hermetic compressor, the displacement which shows the compression capacity of the refrigerant is determined according to the size of the compression chamber 23a. As shown in the present embodiment, the compression chamber 23a is formed of the cylinder 23 body 50. When formed through the inner diameter of the compression chamber forming member 60 is inserted into the hollow portion 51, when replacing only the compression chamber forming member 60 having a different volume of the inner diameter of the cylinder 23 and the frame 30 This is because it is possible to manufacture hermetic compressors having different displacements without replacement. Of course, at this time, the piston 22, of course, should be used in response to the volume change of the compression chamber 23a.

In more detail, the compression chamber forming member 60 has an inner diameter forming the compression chamber 23a to correspond to the diameter of the piston 22 to form a straight cylindrical shape for smooth linear reciprocation of the piston 22. Will be taken.

In addition, the outer diameter of the compression chamber forming member 60 is formed stepped so that the forward direction of the piston 22 is formed larger than the reverse direction of the piston 22, the inner diameter of the hollow portion 51 is such It is formed so as to correspond to the outer diameter of the compression chamber forming member 60, the end of the compression chamber forming member 60 toward the forward direction of the piston 22 is provided to be supported by the valve device (25). .

Therefore, even if the compression chamber forming member 60 is not separately fixed in the state in which it is inserted into the hollow part 51, the valve device 25 and the cylinder head 24 are formed in the body 50 of the cylinder 23. While being coupled to one end, the forward end of the piston 22 is supported by the valve device 25 and can be naturally fixed while not flowing toward the backward direction of the piston 22 due to the stepped structure of its outer diameter. Will be.

In addition, as shown in Figure 4, in the present invention, the compression chamber forming member (60 ') is formed with an insertion protrusion 61 in the outer diameter, the position of the insertion protrusion 61 such that the insertion protrusion 61 is inserted Even when the insertion groove 51a is formed in the inner diameter of the hollow portion 51 of the portion corresponding to the compression chamber forming member 60 ′, it can be prevented from flowing toward the reverse direction of the piston 22.

At this time, the insertion protrusion 61 is formed at the outer diameter side of the reverse direction compression chamber forming member 60 'of the piston 22 or in the longitudinal direction of the compression chamber forming member 60', and the insertion groove 51a is When it is formed in the hollow portion 51 of the corresponding position, the insertion projection (for insertion operation of the compression chamber forming member 60 'inserted into the hollow portion 51 from the forward direction side of the piston 22 ( The length of the insertion groove (51a) is longer than the length of 61, while the compression chamber forming member (60 ') is inserted into the hollow portion 51 in the piston 22 forward direction insertion groove (51a) Since the emptying may cause the refrigerant to leak through such a portion, the insertion protrusion 61 is moved backward from the outer diameter end of the compression chamber forming member 60 'toward the forward direction of the piston 22. It is preferably formed over a predetermined length along the direction, the insertion groove (51a) Is the position corresponding to this insertion projection 61 is formed as a length of the insertion projections 61 are preferred. In addition, the insertion protrusion 61 and the insertion groove 51a may be provided in plural in the circumferential direction at the outer diameter of the compression chamber forming member 60 'and the inner diameter of the hollow portion 51, respectively.

As described above in detail, the hermetic compressor according to the present invention comprises a cylinder having a hollow body and a compression chamber forming member inserted into the hollow to form a compression chamber through its inner diameter. Therefore, when the cylinder structure according to the present invention is adopted, the cylinder having the compression chamber and the frame having the compression chamber can be used in common in the manufacture of the hermetic compressor having different displacements. It is possible to greatly reduce the manufacturing cost in the manufacture of the compressor.

Claims (4)

In a hermetic compressor having a piston having a linear reciprocating motion received from a driving force of a drive unit and a compression chamber in which the piston reciprocates linearly therein. The cylinder includes a body having a hollow portion and a compression chamber forming member provided to be inserted into the hollow portion to form the compression chamber through an inner diameter, so that the displacement can be varied according to the inner diameter of the compression chamber forming member. Hermetic compressor, characterized in that. The method of claim 1, A valve interposed between the cylinder head coupled to one end of the cylinder in the forward direction of the piston to seal the compression chamber, and a valve interposed between the cylinder and the cylinder head to control a flow of refrigerant sucked into or discharged from the compression chamber; Include more devices, The one end of the compression chamber forming member toward the forward direction of the piston is provided to be supported by the valve device. The method of claim 1, The outer diameter of the compression chamber forming member is stepped so that the forward direction of the piston is formed larger than the reverse direction of the piston so as to prevent the compression chamber forming member from falling toward the reverse direction of the piston. The sealed inner compressor is formed so as to correspond to the outer diameter of the compression chamber forming member. The method of claim 1, Insertion protrusions are formed in the outer diameter of the compression chamber forming member so as to prevent the piston forming member from flowing toward the reverse direction of the piston, and an insertion groove is provided in the hollow portion inner diameter at a position corresponding thereto. Hermetic compressor.

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