KR20140112317A - Compressor - Google Patents

Abstract

The present invention relates to a compressor. The inlet side refrigerant tube is bent in the transverse direction and connected to the side surface of the accumulator so that the oscillation center of the compressor casing can be aligned with the axial center of the inlet side refrigerant tube without excessively extending the length of the inlet side refrigerant tube So that even if the accumulator vibrates by the compressor casing, the amplitude of the refrigerant pipe at the inlet side is reduced to reduce the vibration of the refrigeration cycle. In addition, it is possible to prevent the joint portion between the inlet-side refrigerant pipe and the accumulator from being damaged beforehand, thereby enhancing the reliability.

Description

COMPRESSOR

The present invention relates to a compressor, and more particularly to a compressor having an accumulator outside a compressor case.

Generally, a compressor is applied to a vapor compression type refrigeration cycle such as a refrigerator or an air conditioner (hereinafter abbreviated as a refrigeration cycle). The refrigerant compressor has been introduced with a constant-speed compressor driven at a constant speed or an inverter-type compressor controlled in rotation speed.

The compressor is generally referred to as a closed compressor in the case where the compression section operated by the transmission section which is a motorized section and the compression section operated by the transmission section are provided together in the internal space of the closed casing and the case where the transmission section is separately provided outside the casing is referred to as an open compressor have. Most of the refrigeration appliances for home use or commercial use are hermetically sealed compressors.

The compressor can be classified into indirect suction type and direct suction type according to the method of sucking the refrigerant into the compression chamber. In the indirect suction type, the refrigerant circulating in the refrigeration cycle flows into the internal space of the compressor casing and is sucked into the compression chamber. The direct suction type is a type in which the refrigerant is directly sucked into the compression chamber, unlike the indirect suction type.

In the indirect suction type, the liquid refrigerant or oil is filtered by the compressor casing as the refrigerant first flows into the compressor casing, and thus no separate accumulator is provided. On the other hand, the direct suction system prevents the liquid refrigerant or oil from being introduced into the compression chamber The accumulator is normally provided on the suction side.

1 is a longitudinal sectional view showing a rotary compressor having a conventional accumulator. As shown in the figure, a conventional rotary compressor includes a compressor casing 1 in which a compressor 2 is installed, and a compression unit 3 is provided under a compressor casing 2. The transmission section (2) and the compression section (3) are mechanically connected by a crankshaft (23).

The rotor 2 is fixed to the compressor casing 1 by inserting the stator 21 into the compressor casing 1. The rotor 22 is rotatably inserted into the stator 21. A crankshaft (23) is press-fitted to the center of the rotor (22).

The compression section 3 is fixed to the compressor casing 1 at a predetermined interval between the main bearing 31 and the sub bearing 32 so as to support the crankshaft 23. The main bearing 31 and the sub bearing 32, A cylinder 33 for forming a compression space is provided.

A suction port 33a is formed in the cylinder 33 in the radial direction and a refrigerant pipe 42 is connected to the suction port 33a through the compressor casing 1 to form a suction pipe.

An accumulator 4 is disposed on one side of the compressor casing 1 and a refrigerant pipe 41 connected to the evaporator is connected to an upper portion of the accumulator 4, A refrigerant pipe (hereinafter referred to as an outlet side refrigerant pipe) 42 connected to the cylinder 33 of the compressor casing 1 is connected.

The accumulator 4 is fixedly coupled to the side surface of the compressor casing 1 by a bracket 43. The outlet side refrigerant pipe 42 is formed in a L shape and connected to the upper surface of the accumulator 4 and the outlet side refrigerant pipe 42 is formed in an L shape, Respectively.

The inlet-side refrigerant pipe (41) is connected to the center of the upper surface of the accumulator (4).

Reference numerals 11 and 12 denote a discharge pipe and a rolling piston, respectively.

In the conventional rotary compressor as described above, when the power is applied to the transmission portion 2 and the rotor 220 of the transmission portion 2 and the crankshaft 23 rotate, the rolling piston 34 rotates And the refrigerant is sucked into the cylinder 33. The refrigerant is compressed by the rolling piston 34 and a vane (not shown), and is repeatedly discharged through the discharge port (not shown) of the main bearing 31 to the inner space of the casing 1 .

At this time, the refrigerant is separated from the gas refrigerant while passing through the accumulator 4 before being sucked into the cylinder 33, and the gas refrigerant is sucked into the cylinder 33, while the liquid refrigerant is evaporated in the accumulator 4, And then sucked into the cylinder 33.

2, the inlet-side refrigerant pipe 41 connected to the accumulator 4 is located far away from the rotation center RC of the compressor, and the inlet-side refrigerant pipe 41 is connected to the outlet- There is a problem that the center SC of the compressor 1 is spaced apart from the oscillation center VC of the compressor by a predetermined distance t and the vibration transmitted to the accumulator 4 through the compressor casing 1 is greatly increased.

In the conventional compressor, when the inlet side refrigerant tube 41 is coupled to the upper surface of the accumulator 4, the accumulator 4 and the inlet side refrigerant tube 41 are connected to each other, the connecting portion may be broken.

It is an object of the present invention to provide a compressor capable of positioning the center of the inlet side refrigerant tube close to the center of rotation of the compressor while minimizing the length of the inlet side refrigerant tube connected to the accumulator.

Another object of the present invention is to provide a compressor capable of preventing stress concentration between an inlet side refrigerant tube and an accumulator during lateral vibration of a compressor casing and an accumulator, thereby preventing a portion where the inlet side refrigerant tube and the accumulator are connected from being damaged.

In order to achieve the object of the present invention, a compressor having an accumulator outside the casing is characterized in that the accumulator is connected to the accumulator in such a manner that a refrigerant tube for guiding the refrigerant to the accumulator crosses the rotation center line of the compressor. May be provided.

In addition, in the compressor having an accumulator outside the casing, a refrigerant pipe for guiding the refrigerant to the accumulator may be connected to the accumulator, and the refrigerant pipe may be connected to a side of the accumulator.

Further, a casing; A stator fixed to the casing; A rotor rotatably installed inside the stator; A rotating shaft coupled to the rotor and rotating; A plurality of bearing plates fixed to the casing to support the rotation shaft; A cylinder disposed between the plurality of bearing plates to form a compression space; A rolling piston eccentrically connected to the rotary shaft and eccentrically rotated in the cylinder; A vane that reciprocates in contact with the rolling piston to divide the compression space into a suction chamber and a discharge chamber; And an accumulator which is fixed to the casing at the outside of the casing and connected to the refrigerating cycle and the inlet refrigerant pipe and has an oil space to be connected to the outlet refrigerant pipe, And a first center line connected to the space is intersected with a second center line connecting the outlet refrigerant tube to the space.

The compressor according to the present invention is characterized in that the inlet side refrigerant tube is bent in the transverse direction and connected to the side surface of the accumulator so that the vibration center of the compressor casing and the axial center of the inlet side refrigerant tube So that even if the accumulator vibrates by the compressor casing, the amplitude of the refrigerant tube at the inlet side is reduced to reduce the vibration of the refrigeration cycle. In addition, it is possible to prevent the joint portion between the inlet-side refrigerant pipe and the accumulator from being damaged beforehand, thereby enhancing the reliability.

1 is a longitudinal sectional view showing a conventional rotary compressor,
FIG. 2 is a front view showing the position of the inlet side refrigerant tube in the rotary compressor according to FIG. 1,
3 is a longitudinal sectional view showing a rotary compressor according to the present invention,
FIG. 4 and FIG. 5 are a front view and a plan view showing the position of the inlet side refrigerant tube in the rotary compressor according to FIG. 3,
FIG. 6 is an experimental graph for explaining vibration damping effect of each position in the rotary compressor according to FIG. 3;

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

FIG. 3 is a vertical sectional view showing a rotary compressor according to the present invention, and FIGS. 4 and 5 are a front view and a plan view showing the position of an inlet side refrigerant tube in the rotary compressor according to FIG.

As shown in the figure, the rotary compressor according to the embodiment of the present invention includes the compressor casing 1 in which the compressor 2 is installed and the compressing unit 3 is installed under the compressor 2 have. The transmission portion (2) and the compression portion (3) can be mechanically connected by the crankshaft (23).

The transmission section 2 includes a stator 21 which is press-fitted into the compressor casing 1 and fixed to the stator 21, a rotor 22 rotatably inserted into the stator 21, And a crankshaft 23 that is press-fitted into the center of the crankshaft 23.

The compression section 3 includes a main bearing 31 and a sub bearing 32 which are fixedly coupled to the compressor casing 1 to support the crankshaft 23 and a main bearing 31 and a sub bearing 32, A rolling piston 34 which is coupled to the eccentric portion of the crankshaft 23 and compresses the refrigerant while pivotally moving in the cylinder 33; And a vane (not shown) which is pressure-contacted and separates the compression space into a suction chamber and a discharge chamber.

A suction port 33a is formed in the cylinder 33 in a radial direction and a refrigerant pipe 120 through the compressor casing 1 and connected to the suction port can be connected to the suction port 33a.

An accumulator 100 is disposed on one side of the compressor casing 1 and an inlet side refrigerant pipe 110 connected to an evaporator is connected to an upper portion of the accumulator 100. A compressor casing 1 is connected to a lower portion of the accumulator 100, Side refrigerant pipe 120 connected to the cylinder 33 of the refrigerant pipe 120 may be connected.

The accumulator 100 is fixedly connected to the side of the compressor casing 1 by a bracket 130 and the inlet side refrigerant tube 9110 is connected to the side of the accumulator 100 and the outlet side refrigerant tube 120 is connected to the accumulator 100 ) Can be connected to the center of the lower surface.

The inlet side refrigerant pipe 110 and the outlet side refrigerant pipe 120 may each be formed in an L shape. The outlet side refrigerant tube 110 is connected to the lower side of the accumulator 100 while the outlet side refrigerant tube 120 is connected to the lower center of the accumulator 100 and the lower side is connected to the lower side of the compressor casing 1, Respectively.

The inlet side refrigerant pipe 110 may be connected to the outlet of the evaporator which is bent upward in the axial direction and connected to the accumulator 100 in the radial direction to form a refrigeration cycle. 4 and 5, the inlet side refrigerant pipe 110 has a nodal point with the smallest amplitude so that the axial center line SC coincides with the oscillation center VC of the compressor casing 1, So that the vibration of the compressor can be minimized.

In the rotary compressor according to the present invention as described above, when power is applied to the electromotive section 2 so that the rotor 22 of the electromotive section 2 and the crankshaft 23 rotate, the rolling piston 34 rotates The refrigerant is sucked into the cylinder 33 while performing the movement. The refrigerant is compressed by the rolling piston 34 and the vane and is discharged through the discharge port (not shown) provided in the main bearing 31 to the inner space of the compressor casing 1.

At this time, the refrigerant is separated from the gas refrigerant while passing through the accumulator 100 before being sucked into the cylinder 33, so that the gas refrigerant is sucked into the cylinder 33, while the liquid refrigerant is evaporated in the accumulator 100 Lt; / RTI >

In the rotary compressor as described above, not only a rotor such as the rotor 22, the crankshaft 23 and the rolling piston 34 exists in the compressor casing 1, but pressure imbalance occurs in the compression process of the refrigerant The vibration is inevitably generated when the compressor is operated.

Furthermore, since the accumulator 100 is positioned eccentrically from the rotation center RC of the compressor casing 1, the vibration generated during the operation of the compressor is excited, and the refrigerant is guided to the inlet side refrigerant pipe 110 ) May be vibrated and noise may be generated. Therefore, when the inlet side refrigerant tube 110 is located far from the oscillation center of the compressor casing 1, the noise can be further increased while the amplitude of the inlet side refrigerant tube 110 increases.

However, in this embodiment, since the inlet side refrigerant tube 110 is bent in the transverse direction and connected to the side surface of the accumulator 100, the length of the inlet side refrigerant tube 110 is reduced, It is possible to make the axial center of the inlet side refrigerant pipe 110 and the axial center of the inlet side refrigerant pipe 110 coincide with each other. Accordingly, even if the accumulator 100 vibrates by the compressor casing 1, the amplitude of the refrigerant pipe 110 on the inlet side is reduced to reduce the vibration of the refrigeration cycle. 6 is a graph comparing the amplitudes of the case where the inlet side refrigerant pipe 110 is connected to the center of the upper surface of the accumulator 100 (hereinafter, referred to as a conventional case) and the case where the inlet side refrigerant pipe 110 is connected to a side face (hereinafter referred to as the present invention). As shown in the figure, the amplitude of the inlet refrigerant tube is greatly reduced. In particular, it can be seen that the amplitude at the point (point 1) where the accumulator is connected to the inlet refrigerant tube directly receiving the vibration of the accumulator is reduced by about 65%. This is because the fact that the other part (the middle, the point 2 and the point 3 of the inlet side refrigerant tube) is located relatively far from the accumulator while the point 1 is located at the side of the accumulator while the decrease in amplitude is the largest, Is excellent.

As the inlet side refrigerant tube 110 is coupled to the side surface of the accumulator 100, even though the compressor casing 1 and the accumulator 100 vibrate in the lateral direction, the inlet side refrigerant tube 110 and the accumulator 100 It is possible to prevent the joint portion between the inlet side refrigerant pipe 110 and the accumulator 100 from being damaged beforehand, thereby enhancing the reliability. In this case, the stress concentration at the point (1) may be reduced.

1: compressor casing 2:
21: stator 22: rotor
23: rotation shaft 3: compression section
100: Accumulator 110: inlet side refrigerant tube
120: Refrigerant pipe at the outlet side

Claims (4)

1. A compressor having an accumulator outside a casing,
And a refrigerant pipe for guiding the refrigerant to the accumulator is connected to the accumulator in a direction crossing the rotation center line of the compressor. 1. A compressor having an accumulator outside a casing,
The accumulator is connected to a refrigerant pipe for guiding the refrigerant to the accumulator,
And the refrigerant tube is connected to the side of the accumulator. Casing;
A stator fixed to the casing;
A rotor rotatably installed inside the stator;
A rotating shaft coupled to the rotor and rotating;
A plurality of bearing plates fixed to the casing to support the rotation shaft;
A cylinder disposed between the plurality of bearing plates to form a compression space;
A rolling piston eccentrically connected to the rotary shaft and eccentrically rotated in the cylinder;
A vane that reciprocates in contact with the rolling piston to divide the compression space into a suction chamber and a discharge chamber; And
And an accumulator which is fixed to the casing at the outside of the casing and connected to the refrigerating cycle and the inlet refrigerant tube and has an oil space to be connected to the outlet refrigerant tube,
Wherein a first center line connecting the inlet side refrigerant tube to the associated space intersects a second center line connected to the outlet side refrigerant tube. 4. The method according to any one of claims 1 to 3,
And the refrigerant pipe connected to the inlet side of the accumulator is bent so as to coincide with the oscillation center line of the compressor.

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