KR100296246B1 - Cylinder assembly of hermetic rotary compressor - Google Patents

Abstract

PURPOSE: A cylinder assembly of a hermetic rotary compressor is provided to improve suction port so that refrigerant flowing into a suction chamber of a cylinder flows in the direction not interrupting rotation of a rotor. CONSTITUTION: A cylinder assembly of a hermetic rotary compressor includes an upper flange with a discharge outlet, to support an eccentric shaft(21) of a motor; a discharge valve to open and shut the discharge outlet; a lower flange separated from the upper flange, to support the eccentric shaft; a cylinder(33) installed between the upper and lower flanges, having a vane slot(33a) and a suction port(33d) to suck in the refrigerant; a rotor(34) inserted around the eccentric shaft passing through the upper and lower flanges and cylinder, revolving along the inner peripheral surface of the cylinder; a vane(35) installed at the vane slot of the cylinder, to divide the inner space of the cylinder together with the rotor into a suction chamber(33b) and a compression chamber(33c); and a spring(36) elastically supporting the vane to the rotor. The refrigerant flowing into the suction chamber flows in the direction parallel to the tangential direction of revolution of the rotor. Therefore, consumption input required during starting is reduced and the starting capacity and efficiency are improved.

Description

Cylinder assembly of hermetic rotary compressor

The present invention relates to a hermetic rotary compressor used in a refrigerator or an air conditioner.

In general, the hermetic rotary compressor used to compress the refrigerant in a refrigerator or an air conditioner, as shown in FIGS. 1 and 2, has a cylindrical hermetic container 10, a motor 20, and a cylinder assembly 30. It includes.

The motor 20 is press-fitted into the sealed container 10 and has an eccentric shaft 21.

The cylinder assembly 30 is also installed inside the sealed container 10 and has upper and lower flanges 31 and 32, a cylinder 33, a rotor 34, a vane 35, and a spring 36. .

The upper flange 31 and the lower flange 32 rotatably support the eccentric shaft 21 of the motor 20. A discharge port 31a is formed at one side of the upper flange 31, and a discharge valve 37 for opening and closing the discharge port 31a is provided at an upper side thereof.

A cylinder 33 is disposed between the upper flange 31 and the lower flange 32, whereby a predetermined space defined by the upper and lower flanges 31 and 32 and the cylinder 33 is formed.

The rotor 34 is inserted around the eccentric shaft 21 of the motor 20 passing through this space. The cylinder 33 also has a vane slot 33a on one side thereof in communication with this space. The vane 35 is installed in the vane slot 33a so as to be linearly movable. The rear end of the vane 35 is elastically supported by the spring 36, so that the vane 35 always keeps its front end in close contact with the rotor 34. By the vanes 35 and the rotor 34, the inner space of the cylinder 33 is divided into a suction chamber 33b and a compression chamber 33c. The suction chamber 33b of the cylinder 33 is connected to the suction pipe 11 of the container 10 through the suction port 33d, and the compression chamber 33c communicates with the discharge port 31a of the upper flange 31. For reference, reference numeral 40 not described in the drawings is an accumulator.

In this way, the rotor 34 is rotated along the inner circumferential surface of the cylinder 33 by the eccentric shaft 21 of the motor 20, whereby the volume of the suction chamber 33b and the compression chamber 33c is continuously By changing, the suction and compression of the refrigerant occur continuously. When the pressure of the compressed refrigerant is equal to the discharge pressure, the discharge valve 37 is opened, and the compressed refrigerant is discharged to the outside of the cylinder assembly 30 through the discharge port 37.

Then, the vanes 35 provided in the vane slots 33a of the cylinder 33 are continuously reciprocated along the vane slots 33a with their front end being in close contact with the outer circumferential surface of the rotor 34.

However, conventionally, the suction port 33d of the cylinder 33 is formed in the radial direction of the cylinder 33 as shown in FIG. Therefore, the refrigerant sucked into the suction chamber 33d of the cylinder 33 through the suction port 33d flows in a direction that prevents the rotation of the rotor 34. Due to this phenomenon, the consumption input for driving the rotor 34 is increased, and in particular, a large consumption input is required for starting the compressor. Therefore, there is a disadvantage that the maneuverability and efficiency of the compressor is lowered.

An object of the present invention is to provide a cylinder assembly of a hermetic rotary compressor in which the suction port is improved so that the refrigerant flowing into the suction chamber of the cylinder does not interfere with the rotation of the rotor.

1 is a longitudinal sectional view showing a general hermetic rotary compressor;

2 is a plan sectional view showing a cylinder assembly of a conventional hermetic rotary compressor;

And, Figure 3 is a plan sectional view showing a cylinder assembly of the hermetic rotary compressor according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

21; Eccentric axis 33; cylinder

33a; Vane slot 33b; Suction chamber

33c; Compression chamber 33d; Inlet

34; Rotor 35; Bain

The present invention for achieving the above object includes an upper, a lower flange and a discharge valve, a cylinder, a vane and a spring, and a rotor.

The cylinder is divided into the suction chamber and the compression chamber by the vanes and the rotor, and the suction port for guiding the refrigerant gas to be compressed into the suction chamber through which the refrigerant flowing into the suction chamber of the cylinder flows in a direction parallel to the traveling direction of the rotor. It is formed to be.

According to this, the refrigerant gas flowing into the suction chamber through the suction port is pushed in the traveling direction while flowing in parallel with the traveling direction of the rotor. Thus, the consumption input required to drive the rotor, in particular the consumption input required at start-up, is greatly reduced.

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

The cylinder assembly according to an embodiment of the present invention includes an upper and a lower flange, a discharge valve, a cylinder, a rotor, a vane, and the like, which is the same as the cylinder assembly of the conventional rotary compressor shown in FIG. Accordingly, duplicate descriptions of the configuration will be omitted and only the features of the present invention will be described in detail with reference to the cross-sectional view shown in FIG. For reference, the same reference numerals as in the prior art are used for the same components as in the prior art in FIG. 3.

As shown, the eccentric shaft 21 of the motor (not shown) penetrates into the inner space of the cylinder 33, and the rotor 34 is fitted around the eccentric shaft 21. A vane slot 33a is formed at one side of the cylinder 33. The vane slot 33a is provided with a vane 35 so as to be movable in the radial direction of the cylinder 33, and a spring 36 for elastically supporting the vane 35 with respect to the rotor 34 has a vane slot 33a. Is installed at the rear side of the vane 35. The vanes 35 installed in the vane slots 33a divide the inner space of the cylinder 33 together with the rotor 34 into the suction chamber 33b and the compression chamber 33c.

The compression chamber 33c communicates with the discharge port of the upper flange (not shown), and the suction chamber 33b is an accumulator (not shown) through the suction port 33d formed at one side of the vane slot 33a of the cylinder 33. Connected with

Here, the suction port 33d is formed so that its rear side is biased toward the vane slot 33a side. That is, in the conventional case illustrated in FIG. 2, the suction port is formed in the radial direction of the cylinder, but the suction port 33d according to the exemplary embodiment of the present invention is formed to be substantially parallel to the vane slot 33a.

Accordingly, the refrigerant gas flowing through the suction port 33d flows into the suction chamber 33b in a direction substantially parallel to the traveling direction of the rotor 34 rotated along the inner circumferential surface of the cylinder 33.

In this way, the direction in which the refrigerant gas flows into the suction chamber 33b is parallel to the traveling direction of the rotor 34, so that the refrigerant gas flowing into the suction chamber 33b through the suction port 33d is rotated as in the prior art. It does not interfere, but rather pushes the rotor in its direction of travel.

Thus, the required consumption input for rotating the rotor 34 can be greatly reduced. In addition, the rotor 34 can be started more smoothly when the compressor is started.

The present invention as described above is formed such that the refrigerant gas into which the suction port for guiding the refrigerant gas to be compressed into the suction chamber is introduced into the suction chamber in a direction substantially parallel to the traveling direction of the rotor. Therefore, there is an advantage that the consumption input required for driving the rotor, in particular, the consumption input required at start-up is greatly reduced, and the maneuverability and efficiency of the compressor can be greatly improved.

In the above, certain preferred embodiments of the present invention have been illustrated and described. However, the present invention is not limited to the above-described embodiments, and various modifications can be made by those skilled in the art without departing from the gist of the present invention as claimed in the claims. .

Claims (2)

An upper flange having a discharge port, for supporting an eccentric shaft of the motor; A discharge valve for opening and closing the discharge port; A lower flange spaced apart from the upper flange by a predetermined distance and also for supporting an eccentric shaft of the motor; A cylinder installed between the upper flange and the lower flange to form a predetermined internal space, and one side of the cylinder includes a vane slot and a suction port for sucking the refrigerant; A rotor inserted around the eccentric shaft of the motor passing through the upper and lower flanges and the cylinder and rotating along the inner circumferential surface of the cylinder; A vane installed in the vane slot of the cylinder so as to be movable in a straight line and dividing the inner space of the cylinder into a suction chamber and a compression chamber together with the rotor; A cylinder assembly of a hermetic rotary compressor comprising a spring for elastically supporting the vane with respect to the rotor, The inlet of the cylinder is a cylinder assembly of the hermetic rotary compressor characterized in that the refrigerant flowing into the suction chamber of the cylinder through it is formed in a direction parallel to the tangential direction when the rotor rotates. The cylinder assembly of claim 1, wherein the inlet of the cylinder is formed parallel to the vane slot on one side of the vane slot.