KR101311710B1 - Hermetic compressor - Google Patents

Abstract

According to the present invention, the suction ports of the plurality of cylinders communicate with each other, and the suction pipes are connected only to the suction ports of either of them, thereby reducing the number of parts and the assembly labor accordingly, compared to independently connecting the suction pipes to each cylinder. The production cost can be reduced and an increase in compressor vibration due to resonance between the suction pipes can be prevented.

Description

{HERMETIC COMPRESSOR}

1 is a longitudinal sectional view showing an example of the rotary compressor of the present invention,

FIG. 2 is a perspective view of the compression mechanism shown in FIG. 1,

Figure 3 is a longitudinal sectional view showing a suction flow path of the compression mechanism in Figure 1,

4 is a longitudinal cross-sectional view illustrating a process of sucking refrigerant into the first cylinder of FIG. 1;

5 is a longitudinal cross-sectional view illustrating a process of sucking refrigerant into a second cylinder in FIG. 1;
6 is a graph showing the relationship between the compressor input and the communication volume.

Figure 7 is a longitudinal sectional view showing an example in which the suction flow path of the present invention is applied to a variable displacement rotary compressor

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DESCRIPTION OF REFERENCE NUMERALS

100: casing 200: electric mechanism part

300: first compression mechanism 311: first suction port

312: bypass hole 400: second compressor section

410: second cylinder 411: second suction port

500: intermediate bearing 511: communication port

600: accumulator 710: suction tube

720: discharge tube F: communication flow path

V1, V2: first and second compression space

 The double hermetic compressor is connected to a plurality of cylinders, one suction tube, and the present invention relates to a hermetic compressor, and more particularly, to a hermetic compressor capable of supplying refrigerant to a plurality of cylinders with one suction tube.

Generally, the hermetic compressor is provided with a transmission mechanism for generating a driving force in an inner space of a sealed casing and a compression mechanism for receiving the driving force of the transmission mechanism to compress the refrigerant.

The hermetic compressor can be classified into a single hermetic compressor and a double hermetic hermetic compressor according to the number of cylinders.

In the single hermetic compressor, one suction tube is connected to one cylinder, whereas the double hermetic compressor has each suction tube independently connected to a plurality of cylinders.

However, when the suction pipes are independently connected to the plurality of cylinders as described above, the number of the suction pipes increases, thereby increasing the number of parts and increasing the number of assembly operations, thereby increasing the production cost.

In addition, since a plurality of suction pipes are connected to one accumulator and the plurality of suction pipes are connected to the casing, processing and assembly of the accumulator and the casing are difficult, thereby increasing production costs.

In addition, as the vibration generated in the compression mechanism is transmitted through the plurality of suction pipes, the plurality of suction pipes resonate with each other, thereby causing the compressor vibration.

The present invention solves the problems as described above, by using a suction tube in a double hermetic compressor having a plurality of cylinders in common to reduce the number of parts and assembly labor, and at the same time to facilitate the processing of the accumulator and casing, etc. It is an object of the present invention to provide a hermetic compressor that can reduce cost and prevent the vibration transmitted from the compression mechanism unit from being excited.

In order to achieve the object of the present invention, in a hermetic compressor having a plurality of cylinder assemblies having respective compression spaces, a suction pipe is connected only to an inlet of one of the plurality of cylinder assemblies, and the other cylinder assembly is Provided is a hermetic compressor, wherein the suction pipe communicates with a suction port of a connected cylinder assembly.

In addition, a plurality of cylinders are formed up and down in the inner space of the closed casing is formed with a suction port is formed so that each of the compression space for the refrigerant is sucked and compressed and communicate with the respective compression space; And a plurality of bearing plates disposed between the upper and lower side surfaces of the plurality of cylinders and the two cylinders, respectively, to form the plurality of compression spaces separately. A suction pipe is directly connected to a suction port of one of the plurality of cylinders. Is connected, the inlet of the other cylinder is provided with a hermetic compressor which is in communication with the inlet of the cylinder connected to the suction pipe through the communication port provided in the bearing plate between the cylinder.

Hereinafter, a hermetic compressor according to the present invention will be described in detail with reference to an embodiment shown in the accompanying drawings.

1 to 5 show a double rotary compressor as an example of the hermetic compressor of the present invention.

1, a double-acting rotary compressor according to the present invention is provided with a transmission mechanism portion 200 for generating a driving force on the upper side of a closed space of a casing 100, A first compression mechanism 300 and a second compression mechanism 400 for compressing the refrigerant by the rotational force generated in the mechanism unit 200 are provided.

The first compression mechanism 300 includes a first cylinder 310, an upper bearing plate 320, a first rolling piston 330, a first vane 340, A discharge valve 350, and a first muffler 360.

The second compression mechanism 400 includes a second cylinder 410, a lower bearing 420, a second rolling piston 430, a second vane 440, a second discharge valve 450, And a second muffler 460.

An intermediate bearing (not shown) for separating the first compression space V1 of the first cylinder 310 and the second compression space V2 of the second cylinder 410 is disposed between the first cylinder 310 and the second cylinder 410, Plate (hereinafter referred to as intermediate bearing) 500 is provided.

Here, one suction pipe 710 connected to the accumulator 600 is connected to the lower half of the casing 100, and the first compression mechanism 300 and the second compression mechanism 400 are connected to the upper end of the casing 100. One discharge pipe 720 is connected so that the refrigerant discharged into the closed space is delivered to the refrigeration system.

The first suction port 311 of the first compression mechanism 300 is directly connected to the suction pipe 710, and the second suction port 411 of the second compression mechanism 400 is connected to the first compression mechanism 300. The first suction port 311 is connected in parallel via a communication passage (F).

The communication flow path F is connected to the intermediate bearing 500 such that the bypass hole 312 formed in the middle of the first suction port 311 and the bypass hole 312 and the second suction port 411 communicate with each other. It consists of a communication port 511 is formed.

As shown in FIG. 2, the first suction port 311 is formed through the radial direction, the bypass hole 312 is formed through the intermediate bearing 500, the communication hole 511 is formed through the axial direction. The second suction port 411 is formed to be inclined toward the second compression space V2.

The bypass hole 312 may be formed to be smaller than or the same as the diameter of the first suction port 311, the communication hole 511 may be formed to the same diameter as the bypass hole 312, the second suction port ( 411 may be formed to be inclined so that the outlet end can communicate with the inner peripheral surface of the second compression space (V2).

As shown in FIG. 3, the inlet end edge of the bypass hole 312 may be rounded or inclined to allow the refrigerant to smoothly flow into the communication port 511 from the first suction port 311.

The communication port 511 is formed so that the volume is about 1% to 10% of the volume of the compressed space of the second cylinder 410 to directly connect the suction pipe to each cylinder (310, 410) Although it is preferable to prevent the compressor performance from being lowered, the volume of the communication port 511 is formed to be about 3% to 7% of the volume of the compression space V2 of the second cylinder 410 as shown in FIG. 6. It is more desirable to reduce the compressor input.

The second suction port 411 may be formed to be inclined by cutting the edge of the inner peripheral surface of the second cylinder 410, as shown in Figures 2 and 3, although not shown in the drawing to the second cylinder 410 It may be formed so as to be inclined.

In the figure, reference numerals 210 and 210 denote a stator, a rotor, and a rotary shaft, respectively.

The operation and effect of the double rotary compressor of the present invention as described above are as follows.

That is, when the rotor 220 rotates by applying power to the stator 210 of the power mechanism unit 200, the rotation shaft 230 rotates together with the rotor 220 while the power mechanism unit 200 is rotated. The rotational force of the first compression mechanism 300 and the second compression mechanism 400, the first compression mechanism 300 and the second compression mechanism 400, respectively, the first rolling piston 330 and the first 2 the rolling piston 430 and the first vane 340 and the second vane 440 together with the first vane 340 and the second vane 440 while eccentric rotational movement in each of the first compression space (V1) and the second compression space (V2) A suction chamber having a phase difference is formed to suck the refrigerant.

For example, as shown in FIG. 4, when the first compression space V1 starts a suction stroke, refrigerant flows into the first suction port 311 through the accumulator 600 and the suction pipe 710, and the refrigerant flows into the first suction port 311. It is sucked into the first compression space V1 through the first suction port 311 and compressed.

In addition, as shown in FIG. 5, the second compression space of the second cylinder 410 having a phase difference of 180 ° with the first compression space V1 during the compression stroke is performed. V2) also starts the suction stroke. In this case, the second suction port 411 of the second cylinder 410 communicates with the first suction port 311 of the first cylinder 310 through the communication port (including the bypass hole) 511. Refrigerant sucked into the first suction port 311 through the suction pipe 710 bypasses the bypass hole 312 and the communication port 511 and flows into the second suction port 411, and the refrigerant flows into the second compression space. It is sucked into V2 and compressed.

In this way, the refrigerant sucked into one suction pipe 710 is communicated with the first compression space V1 and the second compression space through the communication passage F between the first cylinder 310 and the second cylinder 410. By alternately suctioning to (V2), the number of parts can be reduced, as well as the suction pipe 710 to the casing 100 and the accumulator 600, as compared with the independent connection of the suction pipe to each cylinder (310, 410). The manufacturing cost for the connection can be reduced, thereby reducing the production cost.

Since the vibrations of the compressors generated by the first compression mechanism 300 and the second compression mechanism 400 are transmitted to the single suction pipe 710, the vibration of the compressor due to the resonance is increased It can be prevented in advance.

On the other hand, the double rotary compressor according to the present invention can be applied to a variable displacement double rotary compressor.

For example, the variable displacement double rotary compressor of the present embodiment may include a vane chamber separated from an inner space of the casing 100 at a rear side of the second vane slot (unsigned) of the second cylinder 410 as shown in FIG. 7. 412 is formed, and the vane chamber 412 is connected to the mode switching means 800 that can supply the suction pressure or the discharge pressure in accordance with the operation mode of the compressor. Even in this case, the suction pipe 710 is connected only to the first suction port 311 of the first cylinder 310, and the second suction port 411 of the second cylinder 410 is connected through the communication path F. FIG. The first suction port 311 is communicated with. Detailed configuration and operation thereof is similar to the conventional double rotary compressor described above, so a detailed description thereof will be omitted.

In the rotary compressor according to the present invention, the suction ports of the plurality of cylinders are in communication with each other, and the suction pipes are connected only to the suction ports of either one of them, so that the number of parts and the assembly thereof are higher than those of independently connecting the suction pipes to each cylinder. By reducing the man-hours, the production cost is reduced, and the increase in the vibration of the compressor due to the resonance of the suction pipe can be prevented.

Claims (7)

delete delete A first cylinder having a first suction port configured to communicate with the first compression space and the first compression space; A second cylinder having a second suction port formed in communication with the second compression space and the second compression space; And And an intermediate bearing plate installed between the first cylinder and the second cylinder to separate the first compression space and the second compression space. A suction pipe is connected to the first suction port, The second suction port is in communication with the first suction port through the communication port provided in the intermediate bearing plate, The communication port is formed such that the volume is about 3 to 7% of the volume of the compressed space of the second cylinder, The first suction port is formed in a radial direction, the second suction port is characterized in that the inclined compressor. delete delete The method of claim 3, The communication port is a hermetic compressor, characterized in that formed in the axial direction. The method of claim 3, The suction pipe is hermetic compressor, characterized in that connected to the accumulator so that the refrigerant of the suction pressure is supplied to the cylinder.

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