KR101908301B1 - Condenser having oil separator and Refrigerating cycle apparatus having the same - Google Patents

Abstract

The shell-and-tube type condenser according to the present invention comprises: a shell having an upper portion formed with an inlet through which refrigerant and oil are introduced and an outlet through which refrigerant flows out; An inner tube disposed inside the shell and through which the fluid for condensing the refrigerant passes; An oil collecting plate installed between the inlet and the inner tube and collecting the refrigerant passing through the inlet and the oil in the oil; The heat exchanging performance can be improved by including an oil tube for guiding the oil collected on the oil collecting plate, and it is possible to minimize the size of the other oil separator installed outside the shell-and-tube condenser, There is no need to install an oil separator.

Description

[0001] The present invention relates to a shell-and-tube condenser and a refrigerating cycle apparatus having the same,

The present invention relates to a shell-and-tube condenser and a refrigeration cycle apparatus having the shell-and-tube condenser. More particularly, the present invention relates to a shell-and-tube condenser for collecting oil introduced into a shell by an oil collector plate.

Generally, a refrigeration cycle apparatus includes a compressor in which a refrigerant is circulated, a condenser, an expander, and an evaporator.

In the refrigeration cycle apparatus, the oil can be discharged together with the refrigerant when the compressor is driven, and the oil separator can be installed between the compressor and the condenser.

The oil separator can separate the oil from the refrigerant discharged from the compressor and the oil, and recover the oil through the oil recovery passage to the suction side of the compressor.

Registration Utility Model Bulletin 20-0217628 (2001.01.10)

In the refrigeration cycle apparatus according to the related art, since the oil separator is installed between the compressor and the condenser, space utilization is low, and oil in the condenser and oil in the evaporator can not be efficiently recovered to the compressor.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a shell-and-tube condenser capable of efficiently collecting oil introduced into a shell.

It is another object of the present invention to provide a refrigeration cycle apparatus having a shell-and-tube condenser in which there is no need to provide an oil separator at the outlet side of the compressor or in which the size of the oil separator provided at the outlet side of the compressor can be minimized.

According to an aspect of the present invention, there is provided a shell-and-tube condenser comprising: a shell having an inlet formed at an upper portion thereof and an outlet formed at an upper portion thereof to allow refrigerant to flow therethrough; An inner tube disposed inside the shell and through which a fluid for condensing the refrigerant passes; An oil collecting plate installed between the inlet and the inner tube and collecting the refrigerant passing through the inlet and the oil in the oil; And an oil tube for guiding the oil collected in the oil collecting plate.

A refrigerating cycle apparatus having a shell-and-tube type condenser according to the present invention includes a compressor for compressing refrigerant, a shell-and-tube condenser for condensing the refrigerant compressed by the compressor and having an oil separator built therein, A tube-shaped evaporator for evaporating the refrigerant expanded in the expander; and an ejector mechanism for recovering the oil of the shell-and-tube condenser and the oil of the shell-and-tube evaporator to the compressor, wherein the shell- A tubular condenser having an upper portion formed with an inlet through which refrigerant and oil are introduced, and a lower portion formed with an outlet through which the refrigerant flows; And an inner tube disposed inside the shell and through which a refrigerant for condensing the refrigerant passes, wherein the oil separator is installed between the inlet and the inner tube, and the refrigerant passing through the inlet and the oil collected in the oil, A plate; And an oil tube for guiding the oil collected on the oil collecting plate to the ejector mechanism.

 The ejector mechanism includes an ejector having a main flow path and a merging flow path connected to the main flow path; A suction pipe connecting the compressor and the shell-and-tube evaporator; an ejector discharge flow passage connecting one of the compressors to the main flow path; An evaporator oil recovery passage connecting the confluence passage and the shell-and-tube evaporator; And an ejector suction path connecting the oil tube and the main flow path.

An example of the oil collecting plate may include a mesh and a fixing table to which the mesh is fixed and to which the oil tube is connected.

Another example of the oil collecting plate may include a box body in which a hole is formed in the upper plate and an oil passage is formed in which oil is guided, and the oil tube communicates with the oil passage.

A plurality of the holes may be spaced apart.

The hole may be larger than the inlet.

The hole may be formed in a trapezoidal cross-sectional shape in which the area decreases toward the lower side.

Another example of the oil collecting plate may include a box body in which a grill is formed on a top plate and an oil passage is formed in which oil is guided, and the oil tube communicates with the oil passage.

The oil passage may have an inclined flow path inclined downward toward the oil tube.

The oil collecting plate may be installed to be inclined downward toward the oil tube.

In the present invention, the refrigerant introduced into the shell and the oil in the oil are collected in the oil collecting plate and guided to the oil tube, so that the heat exchange performance can be improved and the size of the other oil separator provided outside the shell- Or it is not necessary to provide a separate oil separator outside the shell-and-tube condenser.

  In addition, one ejector mechanism can recover both the oil of the shell-and-tube condenser and the oil of the shell-and-tube evaporator, and the oil and oil-collecting plate and the oil tube guided to the oil tube after being collected in the oil collector plate Pressure refrigerant gas is used as the driving force of the ejector, so that the structure is simple.

1 is a configuration diagram of a refrigeration cycle apparatus having a shell-and-tube condenser according to the present invention,
2 is a partially cutaway sectional view of a first embodiment of a shell-and-tube condenser according to the present invention,
3 is a perspective view of the oil separator shown in Fig. 2,
4 is a partially enlarged cross-sectional view of a second embodiment of a shell-and-tube condenser according to the present invention,
Fig. 5 is a perspective view of the oil separator shown in Fig. 4,
6 is a partially enlarged cross-sectional view of a third embodiment of a shell-and-tube condenser according to the present invention,
7 is a perspective view of the oil separator shown in Fig. 6,
8 is a partially enlarged cross-sectional view of a fourth embodiment of the shell-and-tube condenser according to the present invention,
Fig. 9 is a perspective view of the oil separator shown in Fig. 8,
10 is a partially enlarged cross-sectional view of a fifth embodiment of a shell-and-tube condenser according to the present invention,
11 is a perspective view of the oil separator shown in Fig.

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

1 is a configuration diagram of a refrigeration cycle apparatus having a shell-and-tube condenser according to the present invention.

A refrigerating cycle apparatus having a shell-and-tube condenser according to the present embodiment includes a compressor 2 for compressing a refrigerant, a shell-and-tube condenser 6 for condensing the refrigerant compressed in the compressor 2 and having an oil separator 4 built therein Tube type evaporator 10 in which the refrigerant expanded in the expander 8 is evaporated and the shell-and-tube type condenser 6 in which the refrigerant condensed in the shell-and-tube type condenser 6 is expanded, And an ejector mechanism 12 for returning the oil of the shell-and-tube evaporator 10 to the compressor 2. The refrigerant is supplied to the compressor 2, the shell-and-tube condenser 6, the inflator 8, - Tubular evaporator (10) is circulated.

In the refrigeration cycle apparatus having a shell-and-tube condenser, a shell-and-tube condenser 6 is connected to a cooling tower (not shown) and cooling water pipes 13 and 14, (Not shown) and the cold water pipes 15 and 16, the cooling water condenses the refrigerant in the shell-and-tube condenser 6, the cold water evaporates the refrigerant in the shell-and-tube evaporator 10, The cold water evaporating the refrigerant in the evaporator 10 may be a chiller used in the cold water consumer. Tube type condenser 6 is connected to a cooling tower (not shown) by cooling water flow paths 13 and 14 and a shell-and-tube type evaporator 10 is connected to a cold water demanding place and cold water flow paths 15 and 16 Explain.

The compressor (2) compresses the refrigerant evaporated in the shell-and-tube evaporator (10), and can be constituted of a rotary compressor, a scroll compressor and a screw compressor, Can be configured to be compressed in multiple stages.

The compressor (2) includes a compression section having a compression chamber in which a refrigerant is compressed, and a motor section for providing a driving force for compressing the refrigerant.

The compressor (2) contains therein oil for preventing damage to the motor unit and the compression unit, and the oil is discharged together with the refrigerant discharged from the refrigerant.

The compressor 2 is connected to the shell-and-tube evaporator 10 through a suction pipe 18 so that the refrigerant evaporated in the shell-and-tube evaporator 10 is sucked into the compressor 2 through the suction pipe 18, The refrigerant discharged from the compressor 2 is discharged to the shell-and-tube condenser 6 through the discharge pipe 20 by the tube-type condenser 6 and the discharge pipe 20.

The refrigeration cycle apparatus having the shell-and-tube condenser is characterized in that the oil separator 4 is built in the shell-and-tube condenser 6 so that there is no need to install a separate oil separator in the discharge pipe 20, A smaller oil separator can be provided if it is not embedded in the tubular condenser 6. Hereinafter, the case where no separate oil separator is provided in the discharge pipe 20 will be described, and the discharge pipe 20 can be connected at one end to the compressor 2 and at the other end to the shell-and-tube condenser 6 .

The oil separator 4 is installed inside the shell-and-tube condenser 6 to collect the oil from the refrigerant and the oil introduced into the shell-and-tube condenser 6.

The shell-and-tube condenser 6 can be connected to the inflator 8 and the inflator connecting pipe 22.

 The shell-and-tube condenser 6 includes a shell 28 having an inlet 24 through which refrigerant and oil are introduced into the upper portion thereof and an outlet 26 through which refrigerant flows out from the lower portion thereof; And an inner tube 30 disposed inside the shell 28 and through which a fluid for condensing the refrigerant passes.

The shell 28 can be connected to the inlet pipe 24 at a discharge pipe 20 and the outlet pipe 26 can be connected to an inflator connecting pipe 22.

The shell 28 is formed with a condensing space in which the refrigerant is condensed while the refrigerant is heat-exchanged with the inner tube 30, and the condensing space can be formed long in the longitudinal direction of the shell 28.

The inner tube 30 can be disposed in the shell 28 in the longitudinal direction of the shell 28 and can be connected to the cooling water pipes 13 and 14. The fluid passing through the inner tube 30 is cooled And can be the cooling water introduced through the piping 13 (14).

The oil separator 4 is installed between the inlet 24 and the inner tube 30 so as to be spaced apart from the inlet 24 so that the upper surface of the oil separator 4 is opposed to the inlet 24 and the refrigerant passing through the inlet 24, An oil collecting plate 32 for directly collecting the oil in the oil and the refrigerant passing through the inlet 24; And an oil tube 34 for guiding the oil collected in the oil collecting plate 32.

The oil collecting plate 32 can function as a collision preventing plate preventing the refrigerant passing through the inlet 24 and the oil from directly colliding with the inner tube 30 and allowing the refrigerant and the oil to flow into the oil collecting plate 32 And then flows into the oil tube 34.

That is, the refrigerant and the oil that have passed through the inlet port 24 first collide with the oil collecting plate 32 at a lower position of the inlet port 24. At this time, the liquid oil flows along the oil collecting plate 32 to the oil tube 34, And the gaseous refrigerant bumps against the oil collecting plate 32 and then flows between the oil collecting plate 32 and the shell 28 and exchanges heat with the inner tube 30 inside the shell 28.

  It is preferable that the oil collecting plate 32 is provided at the lower position of the inlet 24 so as to face the inlet 24 and the area thereof is formed larger than the area of the inlet 24.

The oil tube 34 can be connected to the ejector mechanism 12.

The expander 8 is made up of a capillary tube or electronic expansion valves (EEV) as the refrigerant condensed in the shell-and-tube condenser 6 is expanded.

The shell-and-tube evaporator 10 is connected to an inflator 8 and an inflator connecting line 36.

The shell-and-tube evaporator 10 includes a shell 42 having an inlet 38 through which the refrigerant flows and an outlet 40 through which the refrigerant flows, And may include a tube 44.

The shell 42 may be connected to the inflator connection pipe 36 at the inlet 38 and the suction pipe 18 may be connected to the outlet 40.

The evaporation space in which the refrigerant is evaporated while heat exchange with the inner tube 44 is formed in the shell 42 and the evaporation space may be formed long in the longitudinal direction of the shell 42. [

The inner tube 44 may be disposed in the shell 42 in the longitudinal direction of the shell 42 and may be connected to the cold water pipes 15 and 16. The fluid passing through the inner tube 44 may be water And may be cold water introduced through the piping 15 (16).

The ejector mechanism 12 allows the oil in the shell-and-tube condenser 6 to bypass the expander 8 and the shell-and-tube evaporator 10 to be recovered to the compressor 2, The oil can be returned to the compressor 2 by bypassing the outlet 40 of the shell-and-tube evaporator 10.

The ejector mechanism 12 may include an ejector 54 having a main flow path 50 and a merging flow path 52 connected to the main flow path 50.

The ejector 54 may be formed of a vacuum ejector that causes a suction force to be generated in the confluent flow path 52 when the fluid passes through a narrow portion of the main passage 50. The overall shape of the ejector 54 is a "T" .

The ejector mechanism 12 may be configured such that the high-temperature high-pressure refrigerant and the high-temperature oil flow through the main flow path 50 and the oil of the shell-and-tube type evaporator 10 is sucked into the confluent flow path 52.

The ejector mechanism 12 may include an evaporator oil return flow path 56 connecting the confluence flow path 52 and the shell-and-tube evaporator 10.

The ejector mechanism 12 causes the ejector outlet passage 58 to communicate with the main passage 50 and the suction pipe 18 so that the refrigerant and oil passing through the main passage 50 are sucked into the compressor 2 through the suction pipe 18. [ And the ejector discharge passage 58 can be connected to the main passage 50 and the compressor 2 so that the refrigerant having passed through the main passage 50 and the oil can be directly sucked into the compressor 2 .

The ejector mechanism 12 has a structure in which the ejector suction passage 60 is connected to one of the shell 28 of the shell-and-tube condenser 6, one of the discharge pipe 20 and the oil tube 34, The other end can be connected.

When the ejector suction passage 60 is connected to the discharge pipe 20 and the other end is connected to the main passage 50, the ejector mechanism 12 causes the oil in the oil tube 34 to flow into the ejector suction passage 60 or main And an oil guide passage (not shown) for guiding the oil and refrigerant to the main flow path 50 through the ejector suction flow path 60 and the oil pipe (not shown) The oil and refrigerant flowing into the main flow path 50 through the oil guide flow path are used to generate the driving force of the ejector 54. [

When the ejector suction passage 60 is connected to the shell 28 of the shell-and-tube condenser 6 and the other end is connected to the main passage 50, the ejector mechanism 12 is connected to the oil And an oil guide passage (not shown) for guiding the ejector suction passage 60 to the ejector suction passage 60 or the main passage 50. In the shell 28 of the shell-and-tube condenser 6, And the oil and refrigerant flowing into the main flow path 50 through the oil guide path from the oil tube 34 are used to generate the driving force of the ejector 54. [

One end of the ejector suction passage 60 is connected to the oil tube 34 and the other end of the ejector suction passage 60 can be connected to the main passage 50. The other end of the ejector suction passage 60 flows from the oil tube 34 to the main passage 50 through the ejector suction passage 60, The oil and refrigerant are used to generate the driving force of the ejector 54. [

The ejector mechanism 12 does not require a separate oil guide passage and is simple in structure when the ejector suction passage 60 is connected to the oil tube 34 so that the ejector suction passage 60 is connected to the oil tube 34 .

Hereinafter, the operation of the present invention will be described.

First, when the compressor 2 is driven, the gaseous refrigerant of high temperature and high pressure is discharged from the compressor 2, and the oil in the compressor 2 is discharged to the discharge pipe 20 together with the gaseous refrigerant of high temperature and high pressure.

The refrigerant and oil discharged to the discharge pipe 20 pass through the inlet 24 of the shell-and-tube condenser 6 and enter the shell 28 of the shell-and-tube condenser 6. The refrigerant and oil that have flowed into the shell 28 first collide with the oil collecting plate 32. Part of the oil that is liquid in the refrigerant and the oil is collected in the oil collecting plate 32 and flows into the oil tube 34 and the remainder flows into the lower side of the shell 28 of the shell-and-tube condenser 6. The refrigerant flows partly through the oil collecting plate 32 to the oil tube 34 and flows into the inner tube 30 inside the shell 28 after the remainder flows between the oil collecting plate 32 and the shell 28. [ And is condensed.

The liquid refrigerant condensed inside the shell 28 and the oil that has flowed into the lower inside of the shell 28 of the shell-and-tube condenser 6 flows into the inflator 8 through the outlet 26 and flows into the inflator 8 The refrigerant flowing with the oil is expanded while passing through the expander 8 and flows into the shell-and-tube evaporator 10 together with the oil.

The refrigerant and oil flowing into the shell-and-tube evaporator 10 flows into the shell 42 of the shell-and-tube evaporator 10 and the refrigerant and the refrigerant in the oil are introduced into the shell 42 of the shell- Exchanged with the inner tube 44 and evaporated, and the oil remains in the evaporator 10. The refrigerant evaporated while exchanging heat with the inner tube (44) is sucked into the compressor (2) through the suction pipe (18).

The oil and refrigerant flowing into the oil tube 34 during the circulation of the refrigerant flow into the ejector suction flow path 60 and pass through the main flow path 50 of the ejector 54. A suction force is generated in the confluent flow path 52 of the ejector 54 when the refrigerant and the oil pass through the main flow path 50 of the ejector 54. The oil of the shell- And is sucked into the confluent flow path 52 through the passage. The oil sucked into the confluent flow path 52 is mixed with the refrigerant flowing through the main flow path 50 and the oil and is then returned to the compressor 2 through the ejector discharge flow path 58.

Fig. 2 is a partially cut-away sectional view of a first embodiment of a shell-and-tube condenser according to the present invention, and Fig. 3 is a perspective view of the oil separator shown in Fig.

The oil collection plate 32 shown in Figs. 2 and 3 may include a mesh 70 and a fixing table 72 to which the mesh 70 is fixed and to which the oil tube 34 is connected.

The fixing table 72 can be formed so that the upper surface and the lower surface are opened, and the upper surface is opened and the lower surface is formed to be clogged.

When both the upper and lower surfaces of the fixing table 72 are opened, the oil introduced into the inlet port 24 is caught by the mesh 70 while being collided with the mesh 70 and flows along the mesh 70 and flows into the inlet port 24 The refrigerant may pass through the mesh 70 while colliding with the mesh 70 and then through the lower surface of the oil collecting plate 32 to the lower side of the oil collecting plate 32.

When the upper surface of the fixing table 72 is opened and the lower surface of the fixing table 72 is blocked by the lower plate, the oil introduced into the inlet port 24 is caught by the mesh 70 while being collided with the mesh 70, The refrigerant flowing into the inlet 24 passes through the mesh 70 while colliding with the mesh 70 and then collides with the lower plate of the oil collecting plate 32 and then passes through the upper surface of the holding table 72 again, (72) and the shell (28).

When the upper surface of the fixing table 72 is opened and the lower surface of the fixing table 72 is clogged, oil that can not be filtered by the mesh 70 flows along the lower plate of the fixing table 72 to the oil tube 34 And can be dispersed widely after the refrigerant collides against the lower plate of the fixing table 72. [

The oil collecting plate 32 may be installed to be inclined downward toward the oil tube 34.

When the lower surface of the fixing table 72 is blocked, the oil collecting plate 32 may be formed with a tilted flow path inclined downward toward the oil tube 34 so that the oil flows to the oil tube 34 along the tilted flow path.

4 is a partially enlarged sectional view of a second embodiment of the shell-and-tube condenser according to the present invention, and Fig. 5 is a perspective view of the oil separator shown in Fig.

The oil collecting plate 32 shown in Figs. 4 and 5 has a hole 80 formed in the upper plate and an oil passage 82 for guiding oil therein is formed, and the oil tube 34 is connected to the oil passage 82 And other components and functions other than the oil collecting plate 32 are the same as or similar to those of the shell-and-tube condenser according to the first embodiment of the present invention, and thus a detailed description thereof will be omitted . That is, the oil collecting plate 32 includes an upper plate which forms the upper surface and in which a hole 80 communicating with the oil passage 82 is formed, and a lower hole And an oil passage (82) for guiding the oil passed through the oil passage (80) to the oil tube (34) between the upper and lower plates.

A plurality of holes 80 may be formed spaced apart, and may be formed in a circular or polygonal shape.

It is preferable that the box body 84 is formed to have an area larger than the inlet 24 and that the lower and peripheral surfaces are formed to be clogged so that the oil introduced into the box body 84 does not leak to the periphery of the box body 84 And flows to the oil tube 34 along the oil passage 82.

The oil collecting plate 32 may be horizontally installed at a lower position of the inlet 24 and may be installed at a lower position of the inlet 24 so as to be inclined downward toward the oil tube 34.

When the oil collecting plate 32 is installed horizontally, it is preferable that the oil passage 82 has an inclined flow path inclined downward toward the oil tube.

The shell-and-tube condenser according to the present embodiment is characterized in that the refrigerant having passed through the inlet 24 and the oil are struck against the upper plate of the box body 84 and the oil passes through the hole 80, And then flows into the oil tube 34 through the oil passage 82.

FIG. 6 is a partially enlarged cross-sectional view of a third embodiment of the shell-and-tube condenser according to the present invention, and FIG. 7 is a perspective view of the oil separator shown in FIG.

The oil collecting plate 32 shown in Figs. 6 and 7 is formed such that the hole 90 is formed larger than the inlet 24 and other structures and actions other than the hole 90 are provided in the shell-and-tube condenser 2 The detailed description thereof will be omitted.

That is, the oil collecting plate 32 is formed with a hole 90 larger than the inlet 24 on the upper plate and an oil passage 82 for guiding the oil therein is formed, and the oil tube 34 is connected to the oil passage 82 And may include a communicating box body 84.

In the shell-and-tube condenser according to the present embodiment, refrigerant and oil passing through the inlet 24 pass through the hole 90 of the box body 84 and flow into the box body 84. The oil introduced into the box body 84 collides with the lower plate of the box body 84 and is collected in the oil passage 82 and flows to the oil tube 34 along the oil passage 82. The refrigerant introduced into the box body 84 may collide against the lower plate of the box body 84 and then pass through the hole 90 and may flow between the box body 84 and the shell 28 .

FIG. 8 is a partially enlarged cross-sectional view of a fourth embodiment of the shell-and-tube condenser according to the present invention, and FIG. 9 is a perspective view of the oil separator shown in FIG.

The oil collecting plate 32 shown in FIGS. 8 and 9 is formed in a trapezoidal cross-sectional shape in which the area of the hole 100 decreases as it goes downward, and other structures and actions other than the hole 100 are formed in the shell -Tubular condenser The second embodiment is similar to or similar to the second embodiment, and therefore, detailed description thereof will be omitted.

That is, the oil collecting plate 32 is formed with a hole 100 having a trapezoidal cross-sectional shape in the upper plate and an oil passage 82 for guiding the oil therein is formed and the oil tube 34 is communicated with the oil passage 82 And may include a box body 84.

 The oil collecting plate 32 may be formed such that the protruding portion 102 formed in the hole 100 and opened in the up and down direction protrudes toward the inside of the box body 84. The protruding portion 102 has an opening area Can be reduced.

In the shell-and-tube condenser according to the present embodiment, refrigerant and oil passing through the inlet 24 pass through the hole 100 of the box body 84 and flow into the box body 84. The oil introduced into the box body 84 collides with the lower plate of the box body 84 and is collected in the oil passage 82 and flows to the oil tube 34 along the oil passage 82. On the other hand, a part of the oil impinging on the lower plate of the box body 84 may flow toward the hole 100, but is prevented from being splashed to the upper side of the box body 84 by being blocked by the protrusion 102.

10 is a partially enlarged sectional view of a fifth embodiment of the shell-and-tube condenser according to the present invention, and Fig. 11 is a perspective view of the oil separator shown in Fig.

The oil collecting plate 32 shown in Figs. 10 and 11 has a grill 110 formed on the upper plate and an oil passage 82 for guiding oil therein is formed, and the oil tube 34 is connected to the oil passage 82 And other components and operations other than the oil collecting plate 32 are the same as or similar to those of the second embodiment of the shell-and-tube type condenser according to the present invention, and a detailed description thereof will be omitted .

The grill 110 functions to disperse the refrigerant and the oil introduced through the inlet 24 and has a round cross sectional shape so that the oil in the oil passage 82 flows through the gap between the grilles 110 It is possible to minimize splashing to the upper side of the box body 84.

2: compressor 4: oil separator
6: shell-tube type condenser 8: inflator
10: shell-tube evaporator 12: ejector mechanism
24: inlet 26: outlet
28: shell 30: inner tube
32: Oil collecting plate 34: Oil tube
50: main flow path 52: confluent flow path
54: Ejector 56: Evaporator oil recovery flow path
58: Ejector discharge channel 60: Ejector suction channel
70: mesh 72:
80: hole 82: oil channel
84: box body 90: hole
100: Hole 110: Grill

Claims (20)

A shell having an upper portion formed with an inlet through which refrigerant and oil are introduced and an outlet through which the refrigerant flows out;
An inner tube disposed inside the shell and through which a fluid for condensing the refrigerant passes;
And an upper surface is opposed to the inlet so that the refrigerant and the oil which have passed through the inlet are directly collided with the upper surface and the refrigerant passing through the inlet and the oil in the oil are collected in the space between the inlet and the inlet tube, An oil collecting plate on which an oil passage for guiding the collected oil therein is formed;
And an oil tube coupled to the oil collecting plate and communicating with the oil passage and guiding the oil collected in the oil collecting plate,
The oil collecting plate may include:
An upper plate forming the upper surface and having a hole communicating with the oil channel vertically,
And a lower plate spaced downward from the upper plate and opposed to the upper plate, the lower plate forming the oil passage between the oil passage and the upper plate for guiding the oil passed through the hole to the oil tube. The method according to claim 1,
Wherein the oil collecting plate includes a plurality of holes formed in the mesh and installed in the upper plate. delete The method according to claim 1,
And a plurality of the holes are spaced apart from each other. The method according to claim 1,
And the holes are formed to be larger than the inlet. The method according to claim 1,
Tube type condenser in which a plurality of holes are formed in a trapezoidal cross-sectional shape that decreases in area toward the lower side. The method according to claim 1,
Wherein the oil collecting plate has the holes formed between a plurality of grills formed in a round cross-sectional shape on the upper plate. The method according to any one of claims 1 to 6,
Wherein the oil passage has an inclined flow path inclined downward toward the oil tube. The method according to claim 1,
Wherein the oil collection plate is inclined downwardly toward the oil tube. A compressor for compressing the refrigerant,
A shell-and-tube condenser in which the refrigerant compressed in the compressor is condensed and the oil separator is built in,
An expander in which the refrigerant condensed in the shell-and-tube type condenser is expanded,
A shell-and-tube evaporator in which the refrigerant expanded in the inflator is evaporated,
And an ejector mechanism for recovering the oil of the shell-and-tube condenser and the oil of the shell-and-tube evaporator to the compressor,
The shell-and-tube type condenser includes a shell having an inlet through which refrigerant and oil are introduced into the upper portion and an outlet through which refrigerant flows out from the lower portion; And an inner tube disposed inside the shell and through which a fluid for condensing the refrigerant passes,
The oil separator includes:
And an upper surface is opposed to the inlet so that the refrigerant and the oil which have passed through the inlet are directly collided with the upper surface and the refrigerant passing through the inlet and the oil in the oil are collected in the space between the inlet and the inlet tube, An oil collecting plate for guiding the oil collected therein;
And an oil tube coupled to the oil collecting plate to communicate with the oil passage and to guide the oil collected in the oil collecting plate to the ejector mechanism,
The oil collecting plate may include:
An upper plate forming the upper surface and having a hole communicating with the oil channel vertically,
And a lower plate spaced downward from the upper plate to be opposed to the upper plate and forming the oil passage between the upper and lower plates for guiding oil passed through the holes to the oil tube, / RTI > 11. The method of claim 10,
The ejector mechanism includes an ejector having a main flow path and a merging flow path connected to the main flow path;
A suction pipe connecting the compressor and the shell-and-tube evaporator; an ejector discharge flow passage connecting one of the compressors to the main flow path;
An evaporator oil recovery passage connecting the confluence passage and the shell-and-tube evaporator;
And an ejector suction flow passage for connecting the oil tube and the main flow passage. The method according to claim 10 or 11,
And the oil collecting plate has a shell-and-tube condenser including a plurality of holes formed in the upper plate. delete delete The method according to claim 10 or 11,
Wherein the holes have a shell-and-tube condenser in which a plurality of holes are spaced apart. The method according to claim 10 or 11,
Tube type condenser in which one of the holes is formed larger than the inlet. The method according to claim 10 or 11,
Tube type condenser in which a plurality of holes are formed in a trapezoidal cross-sectional shape decreasing in area toward the lower side. The method according to claim 10 or 11,
Wherein the oil collecting plate has a shell-and-tube condenser in which the holes are formed between a plurality of grills formed in a round cross-sectional shape on the upper plate. The method according to claim 10 or 11,
And the oil passage has a shell-and-tube condenser having an inclined flow path inclined downward toward the oil tube. The method according to claim 10 or 11,
Wherein the oil collecting plate has a shell-and-tube condenser installed downwardly inclined toward the oil tube.

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