KR200382995Y1 - Accmulator for twin rotary compressor - Google Patents

Abstract

The present invention relates to an accumulator for a double rotary compressor, which can be installed without tilting the outlet pipe of the accumulator, prevents noise, improves reliability, and reduces the manufacturing cost of the accumulator for a double rotary compressor. It is about.

To this end, the present invention is a double rotary compressor having a plurality of compression units and each suction unit has a suction pipe independently, and provided with a screen for separating the liquid refrigerant and the gaseous refrigerant therein, and a space for accommodating the liquid refrigerant and the gaseous refrigerant. A housing having a; An inlet pipe installed at an upper end of the housing and into which refrigerant is introduced; The gaseous refrigerant separated by the screen is installed to penetrate the lower end of the housing so that it can flow out into the respective compression units, the inlet end of which is disposed inside the housing, and the outlet end of which is disposed outside of the housing. A plurality of outlet pipes connected to the suction pipes; It is disposed in the housing provides a accumulator for a double rotary compressor, characterized in that it comprises a; fixed tube for fixing in communication with the inlet end of each outlet pipe collectively.

Description

Accumulator for double rotary compressors {ACCMULATOR FOR TWIN ROTARY COMPRESSOR}

The present invention relates to an accumulator for a double rotary compressor, and more particularly, it is possible to install the outflow pipe of the accumulator without tilting, and to prevent the noise and improve the reliability according to the double rotary that can reduce the manufacturing cost. It relates to an accumulator for a compressor.

In general, a compressor converts mechanical energy into compressive energy of a compressive fluid, and is generally classified into reciprocating type, scroll type, centrifugal type, and vane type.

The rotary compressor is mainly applied to an air conditioner such as an air conditioner. Recently, a so-called double rotary compressor having a plurality of compression parts by symmetrically forming an eccentric portion of a rotating shaft so as to reduce the unloading load has been proposed.

1 is a longitudinal cross-sectional view showing the structure of a conventional double rotary compressor, Figure 2 is a vertical cross-sectional view showing the structure of an accumulator as a conventional double rotary compressor, Figure 3 is a longitudinal cross-sectional view showing the structure of another conventional accumulator. to be.

As shown in FIGS. 1 and 2, a conventional double rotary compressor includes a casing 1 in which a plurality of refrigerant suction pipes SP1 and SP2 and a refrigerant discharge pipe DP communicate with each other, and the casing 1. ) Is installed on the upper side of the power transmission unit (2) consisting of a stator (2a) and the rotor (2b) to generate a rotational force, and the rotational force generated by the transmission mechanism (2) installed up and down under the casing (1) It is composed of a first compression mechanism portion 10 and the second compression mechanism portion 20 for receiving the by the rotary shaft 3 to compress the refrigerant, respectively.

In addition, an accumulator 30 for separating the liquid refrigerant from the suction refrigerant is connected to the inlet side of each of the compression mechanism units 10 and 20, and the outlets of the accumulator 30 are respectively connected to the first cylinder 11 to be described later. It is connected to the inlet port 11a and the inlet port 21a of the second cylinder 21.

The first compression mechanism part 10 is formed in an annular shape and covers the first cylinder 11 installed inside the casing 1, and both upper and lower sides of the first cylinder 11, together with the first inner space V1. The main bearing 12 and the middle bearing 13 to support the rotating shaft 3 in the radial direction and rotatably coupled to the upper eccentric portion of the rotating shaft 3 to form a first cylinder of the first cylinder 11. The first rolling piston 14 which compresses the refrigerant while turning in the inner space V1, and is radially movable to the first cylinder 11 so as to be pressed against the outer circumferential surface of the first rolling piston 14. A first vane (not shown) for dividing the first inner space V1 of the first cylinder 11 into the first suction chamber and the first compression chamber, and a first discharge port provided near the center of the main bearing 12. (12a) a first discharge valve 15 which is coupled to the front end so as to be openable and closed to control the discharge of the refrigerant gas discharged from the first compression chamber. Lost

The second compression mechanism 20 is formed in an annular shape and covers the second cylinder 21 installed below the first cylinder 11 inside the casing 1 and both the upper and lower sides of the second cylinder 21. The middle bearing 13 and the sub bearing 22 supporting the rotating shaft 3 in the radial and axial directions while forming the second inner space V1 are rotatably coupled to the lower eccentric portion of the rotating shaft 3. The second rolling piston 23 to compress the refrigerant while turning in the second inner space V2 of the second cylinder 21 and the outer circumferential surface of the second rolling piston 23 to press the second cylinder 21. A second vane (not shown) which is radially movably coupled to the second cylinder 21 and divides the second inner space V2 of the second cylinder 21 into a second suction chamber and a second compression chamber, and the sub-bearing 22. Coupled to the front end of the second discharge port 22a provided near the center of the pump to control the discharge of the refrigerant gas discharged from the second compression chamber. It is made up of the second discharge valve 24.

On the other hand, the accumulator 30 is provided with a screen 32 for separating the liquid refrigerant and the gaseous refrigerant therein, a housing 31 having a space for receiving the liquid refrigerant and the gaseous refrigerant, and an upper end of the housing 31. It is installed in the inlet tube 33 and the "L" shape and is installed to penetrate through the lower end of the housing 31, one end is disposed below the screen 32 and the other end of the first cylinder ( 11) and the first outlet pipe 34 and the second outlet connected to the first refrigerant suction pipe SP1 and the second refrigerant suction pipe SP2 respectively connected to the suction ports 11a and 21a of the second cylinder 21, respectively. It consists of a tube (35).

The housing 31 is composed of an upper housing 31a to which the inlet pipe 33 is connected, and a lower housing 31b to which the respective outlet pipes 34 and 35 are inserted and coupled to the lower housing 31b. ), The aforementioned first outlet pipe 34 and the second outlet pipe 35 are independently coupled to each other.

In the figure, reference numeral 32a denotes a screen hole.

The conventional double rotary compressor as described above operates as follows.

When power is applied to the stator 2a of the power transmission mechanism 2 and the rotor 2b rotates, the rotating shaft 3 rotates together with the rotor 2b, thereby rotating the rotational force of the power transmission mechanism 2 to the first compression mechanism portion. 10 and the second compression mechanism 20 to be transferred to each of the rolling pistons 14, 23 eccentrically in each cylinder (11) (21), so that the refrigerant gas is the first cylinder (11) And alternately sucked into the respective suction spaces through the first refrigerant suction pipe SP1 and the second refrigerant suction pipe SP2 connected to the second cylinder 21, and then compress each of the discharge ports 12a and 22a to a predetermined pressure. Through a series of processes are alternately discharged into the casing (1) through.

At this time, the first refrigerant suction pipe SP1 and the second refrigerant suction pipe SP2 are connected to the first outlet pipe 34 and the second outlet pipe 35 which are inserted into and coupled to the housing 31 of the accumulator 30. Bar, the gaseous refrigerant flowing into the housing 31 and passing through the screen 32 is the suction space of the cylinders 11 and 21 through each of the outlet pipes 34 and 35 and the refrigerant suction pipes SP1 and SP2. The liquid refrigerant, which is sucked into each of the screens 32, is collected at the bottom of the housing 31 through the screen hole 32a and then vaporized by surrounding heat, and is then elevated again to the respective outlet pipes 34 and 35. It is sucked into the suction space of the cylinders 11 and 21 through the refrigerant suction pipes SP1 and SP2.

By the way, in the accumulator of the conventional double rotary compressor, the outlet pipes 34 and 35 are inserted into the lower end of the housing 31 to be fixed by welding. Outflow pipes 34 and 35 are inclined, and various noises are generated and reliability is lowered.

That is, when the outlet pipes 34 and 35 are fixed to the housing 31 by welding, the outlet pipes 34 and 35 are inclined and come into contact with each other. There was a problem in that abnormal noise was generated, and the liquid refrigerant filtered by the screen 32 directly flowed into each of the outlet pipes 34 and 35 to cause abnormal wear, and thus, reliability was lowered.

To this end, as shown in FIG. 3, a separate holder 36 is installed inside the housing 31, and each outlet pipe 34 and 35 is inserted into the holder 36 and can be fixed without tilting. It was.

However, the holder 36 is not easy to install, and there is a problem in that abnormal noise is generated between the holder 36 and each of the outlet pipes 34 and 35 due to the vibration generated during the operation of the compressor.

Therefore, the present invention has been devised to solve the above problems, it is possible to install the outflow pipe of the accumulator without tilting, as well as to prevent noise and improve the reliability according to the double, which can reduce the manufacturing cost It is an object of the present invention to provide an accumulator for a rotary compressor.

The present invention for achieving the above object is a double rotary compressor having a plurality of compression units and each of the compression unit independently of the suction pipe, there is provided a screen for separating the liquid refrigerant and the gaseous refrigerant therein and also the liquid refrigerant and A housing having a receiving space for the gas phase refrigerant; An inlet pipe installed at an upper end of the housing and into which refrigerant is introduced; The gaseous refrigerant separated by the screen is installed to penetrate the lower end of the housing so that it can flow out into the respective compression units, the inlet end of which is disposed inside the housing, and the outlet end of which is disposed outside of the housing. A plurality of outlet pipes connected to the suction pipes; And a fixing tube disposed inside the housing to fix the inlet ends of the respective outlet pipes collectively.

The fixed tube may include a main tube disposed below the screen, and a plurality of branch pipes integrally formed in communication with the bottom of the main tube and coupled to the inlets of the respective outlet pipes. It is characterized by.

In addition, each branch pipe (枝 管) is characterized in that coupled to each outlet pipe by welding or press-fit.

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

4 is a longitudinal sectional view showing the structure of a double rotary compressor equipped with an accumulator according to the present invention, Figure 5 is a longitudinal sectional view showing the main part of FIG.

3 to 4, the double rotary compressor according to the present invention, the casing 101 is installed so that a plurality of refrigerant suction pipe (SP1) (SP2) and refrigerant discharge pipe (DP) in communication with the casing, It is installed on the upper side of the 101 and the electric mechanism unit 102 composed of the stator 102a and the rotor 102b so as to generate a rotational force, and is installed up and down under the casing 101 to be generated in the electric mechanism unit 102 The gaseous refrigerant is sucked into the first compression mechanism part 110 and the second compression mechanism part 120, and each of the compression mechanism parts 110 and 120, respectively, to receive the rotational force to be transmitted by the rotation shaft 103 to compress the refrigerant. It is configured to include the accumulator 130 of the present invention is connected to the inlet side of each compression mechanism 110, 120 so as to separate the liquid refrigerant from the suction refrigerant.

The first compression mechanism part 110 is formed in an annular shape and covers the first cylinder 111 installed inside the casing 101 and both the upper and lower sides of the first cylinder 111 together with the first inner space V1. And the main bearing 112 and the middle bearing 113 to radially support the rotating shaft 103 and rotatably coupled to the upper eccentric portion of the rotating shaft 103 to form a first cylinder of the first cylinder 111. A first rolling piston 114 that compresses the refrigerant while turning in the inner space V1, and is radially movable to the first cylinder 111 so as to be press-contacted to an outer circumferential surface of the first rolling piston 114. A first vane (not shown) for dividing the first inner space V1 of the first cylinder 111 into the first suction chamber and the first compression chamber, and a first discharge port provided near the center of the main bearing 112. A first discharge ball coupled to the front end and openable to control the discharge of the refrigerant gas discharged from the first compression chamber. It consists of 115.

The second compression mechanism 120 is formed in an annular shape to cover the second cylinder 121 installed below the first cylinder 111 inside the casing 101 and both the upper and lower sides of the second cylinder 121. Middle bearing 113 and sub-bearing 122 for supporting the rotating shaft 103 in the radial and axial direction while forming a second inner space (V1) and rotatably coupled to the lower eccentric portion of the rotating shaft 103 The second rolling piston 123 to compress the refrigerant while turning in the second inner space V2 of the second cylinder 121 and the outer circumferential surface of the second rolling piston 123 to press-contact the second cylinder 121. A second vane (not shown) which is radially coupled to the second cylinder 121 and divides the second inner space V2 of the second cylinder 121 into a second suction chamber and a second compression chamber, and the sub-bearing 122. Refrigerant gas discharged from the second compression chamber is coupled to the front end of the second discharge port (122a) provided near the center of the It consists of a second discharge valve 124 for controlling the discharge.

On the other hand, the accumulator 130 of the present invention is provided with a screen 132 for separating the liquid refrigerant and the gaseous refrigerant therein and a housing 131 having a receiving space for the liquid refrigerant and the gaseous refrigerant; An inlet pipe 133 installed at an upper end of the housing 131 to introduce a refrigerant; The gaseous refrigerant separated by the screen 132 is formed in an “L” shape so as to flow out to each of the compression mechanism parts 110 and 120, and is installed to penetrate the lower end of the housing 131. It is disposed inside the housing 131, the outlet end is disposed outside the housing 131 and is connected to each of the inlet (111a) (121a) of the first cylinder 111 and the second cylinder 121 A first outlet pipe 134 and a second outlet pipe 135 connected to the first refrigerant suction pipe SP1 and the second refrigerant suction pipe SP2, respectively; And a fixing tube 136 disposed in the housing 131 to fix the inlet ends of the outlet pipes 134 and 135 to communicate with each other collectively.

The housing 131 is composed of an upper housing 131a to which the inlet pipe 133 is connected, and a lower housing 131b to which the outlet pipes 134 and 135 are inserted and coupled, and the lower housing 131b. The first outlet pipe 134 and the second outlet pipe 135 described above are each independently coupled by welding.

The fixed pipe 136 is formed integrally to communicate with the bottom of the main pipe (136a) and the bottom of the main pipe (136a) disposed on the lower side of the screen 132 of each of the outlet pipe (134, 135) As a kind of manifold including a plurality of branch pipes 136b coupled to the inlet, the inlet end of each outlet pipe 134 and 135 can be fixed in a batch. The inlet end of each outflow pipe 134, 135 is integrally coupled to the branch pipe 136b of the fixed pipe 136 by welding or indentation.

In the drawings, reference numeral 132a denotes a screen hole.

The compressor including the accumulator of the present invention as described above has the following effects.

When power is applied to the stator 102b of the electric mechanism part and the rotating shaft 103 rotates together with the rotor 102b, each rolling piston 114 of the first compression mechanism part 110 and the second compression mechanism part 120 ( 123 repeats a series of processes in which the refrigerant gas is sucked, compressed and alternately discharged while eccentrically rotating in the respective cylinders 111 and 121.

At this time, the first refrigerant suction pipe (SP1) and the second refrigerant suction pipe (SP2) coupled to each of the compression mechanism (110) 120, the first outlet pipe 134 inserted into the housing 131 of the accumulator 130. ) And the second outlet pipe 135, the gaseous refrigerant flowing into the housing 131 and passing through the screen 132 is fixed pipe 136, each outlet pipe 134, 135, and a refrigerant suction pipe. While each of the liquid refrigerant is sucked into the suction spaces of the cylinders 111 and 121 through SP1 and SP2, the liquid refrigerant filtered through the screen 132 accumulates at the bottom of the housing 131 through the screen hole 132a. As it rises while being vaporized by heat, it is sucked into the suction space of the cylinders 111 and 121 through the fixing pipe 136, the outlet pipes 134 and 135, and the refrigerant suction pipes SP1 and SP2.

Here, each outlet pipe 134, 135 of the accumulator 130 is in communication with the inlet end is fixed by the fixed pipe 136 disposed in the interior of the housing 131, such that it is fixed in a batch The structure allows each outlet pipe 134 and 135 to be fixed without tilting when fixed to the housing 131 by welding, thereby preventing the problem of noise and reliability deterioration due to the tilt of the conventional outlet pipe. And it is possible to reduce the material cost required to manufacture each outlet pipe (134, 135).

In addition, such a fixed tube 136 can be fastened through a simple assembly process compared to the conventional holder can simplify the assembly process of the accumulator 130 as a whole, it is possible to improve the productivity.

In the above described a preferred embodiment of the present invention by way of example, the scope of the present invention is not limited to only this specific embodiment, it can be changed appropriately within the scope described in the utility model claims.

As seen above, according to the accumulator for a double rotary compressor according to the present invention, it is possible to install the outflow pipe of the accumulator without tilting, as well as to prevent the noise and improve the reliability, and to reduce the manufacturing cost and assembly process It has the effect of simplifying.

1 is a longitudinal sectional view showing the structure of a conventional double rotary compressor;

FIG. 2 is a vertical cross-sectional view showing a structure of an accumulator as a conventional double rotary compressor. FIG.

Figure 3 is a longitudinal sectional view showing the structure of another conventional accumulator

Figure 4 is a longitudinal sectional view showing the structure of a double rotary compressor equipped with an accumulator according to the present invention

5 is a longitudinal sectional view showing the structure of an accumulator according to the present invention;

<Explanation of symbols for the main parts of the drawings>

101: casing 102: electric mechanism part

110,120: Compressor part 130: Accumulator

131: housing 132: screen

133: inlet pipe 134,135: outlet pipe

136: fixed tube 136a: main building

136b: branch pipe

Claims (3)

A double rotary compressor having a plurality of compression units and having a suction pipe for each compression unit independently, A housing having a screen separating the liquid refrigerant and the gaseous refrigerant therein and having a receiving space for the liquid refrigerant and the gaseous refrigerant; An inlet pipe installed at an upper end of the housing and into which refrigerant is introduced; The gaseous refrigerant separated by the screen is installed to penetrate the lower end of the housing so that it can flow out into the respective compression units, the inlet end of which is disposed inside the housing, and the outlet end of which is disposed outside of the housing. A plurality of outlet pipes connected to the suction pipes; The accumulator of claim 2, wherein the accumulator is disposed inside the housing to fix the inlet end of each outlet pipe so as to communicate with each other collectively. The method of claim 1, The fixed tube is configured to include a main pipe disposed in the lower side of the screen and a plurality of branch pipes integrally formed in communication with the bottom of the main pipe and coupled to the inlets of the respective outlet pipes. Accumulator of double rotary compressor to be. The method of claim 2, Wherein each branch pipe is coupled to each outlet pipe by welding or press-fitting.