KR20120124710A - Condenser having oil separator and Refrigerating cycle apparatus having the same - Google Patents

Abstract

PURPOSE: A shell-tube condenser having an oil separator and refrigerating cycle apparatus having the same are provided to improve heat exchange performance. CONSTITUTION: A shell-tube condenser comprises a shell(28), an inner tube(30), an oil drip tray(32), and an oil tube(34). The upper portion of the shell comprises an oil inlet and a coolant outlet. The inner tube is arranged in the shell. Fluid for condensing the coolant passes through the inner tube. The oil drip tray is installed between the oil inlet and the inner tube. The oil tube guides the oil collected by the oil drip tray.

Description

Condenser having oil separator and Refrigerating cycle apparatus having the same

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shell-tube condenser and a refrigeration cycle apparatus having the same, and more particularly, to a shell-tube condenser and a refrigeration cycle apparatus having the oil collection plate collecting oil introduced into the shell by installing an oil collecting plate inside the shell.

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

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

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

Registered Utility Model Publication 20-0217628 (2001.01.10)

The refrigeration cycle apparatus according to the prior art has a problem that the oil separator is installed between the compressor and the condenser, the space utilization is low, and the oil in the condenser and the oil in the evaporator are not efficiently recovered by the compressor.

The present invention has been made to solve the above problems of the prior art, an object of the present invention is to provide a shell-tube type condenser that can efficiently collect the oil introduced into the shell.

Another object of the present invention is to provide a refrigeration cycle apparatus having a shell-tube type condenser that does not need to install an oil separator on the outlet side of the compressor or minimizes the size of the oil separator installed on the outlet side of the compressor.

Shell-tube type condenser according to the present invention for solving the above problems is formed with an inlet for the refrigerant and oil inlet is formed in the upper portion and the shell formed with an outlet for the refrigerant flows in the lower portion; An inner tube disposed inside the shell and through which fluid condensing the refrigerant passes; An oil collecting plate installed between the inlet and the inner tube and collecting oil from the refrigerant and oil passing through the inlet; It includes an oil tube for guiding the oil collected on the oil collecting plate.

A refrigeration cycle apparatus having a shell-tube condenser according to the present invention includes a compressor for compressing a refrigerant, a shell-tube condenser in which the refrigerant compressed in the compressor is condensed and an oil separator is built in, and the refrigerant condensed in the shell-tube condenser. A expander to which the gas is expanded, a shell-tube evaporator in which the refrigerant expanded in the expander is evaporated, and an ejector mechanism for recovering the oil of the shell-tube condenser and the oil of the shell-tube evaporator to the compressor. The tubular condenser has a shell formed with an inlet through which a refrigerant and an oil flow in the upper portion, and an outlet through which the refrigerant flows out in the lower portion; An inner tube disposed inside the shell and through which fluid condensing the refrigerant passes, wherein the oil separator is installed between the inlet and the inner tube and collects oil in the oil and the refrigerant passing through the inlet. Plate; And an oil tube for guiding oil collected on the oil collecting plate to the ejector mechanism.

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

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

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

A plurality of holes may be formed spaced apart.

The hole may be formed 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 the top plate, an oil passage through which oil is guided is formed, and the oil tube is in communication with the oil passage.

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

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

According to the present invention, since the oil and the refrigerant in the oil introduced into the shell are collected in the oil collecting plate and guided to the oil tube, heat exchange performance can be improved and the size of other oil separator installed outside the shell-tube condenser is minimized. Or there is no need to install a separate oil separator outside the shell-tube condenser.

  In addition, one ejector mechanism can recover both the oil of the shell-tube condenser and the oil of the shell-tube evaporator to the compressor, and collects the oil and the oil collecting plate and the oil tube guided to the oil tube after being collected from the oil collecting plate. Since the high-pressure refrigerant gas passed through is used as the driving force of the ejector, the structure has a simple advantage.

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

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

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

The refrigeration cycle apparatus having a shell-tube type condenser according to the present embodiment includes a compressor (2) for compressing a refrigerant, and a shell-tube type condenser (6) in which the refrigerant compressed in the compressor (2) is condensed and the oil separator (4) is incorporated. ), An expander 8 in which the refrigerant condensed in the shell-tube condenser 6 expands, a shell-tube evaporator 10 in which the refrigerant expanded in the expander 8 evaporates, and a shell-tube condenser 6. Oil and an ejector mechanism (12) for recovering oil from the shell-tube evaporator (10) to the compressor (2), the refrigerant comprising a compressor (2), a shell-tube condenser (6), an expander (8) and a shell. -Circulate the tubular evaporator 10.

In a refrigeration cycle apparatus having a shell-tube condenser, a shell-tube condenser 6 is connected to a cooling tower (not shown) and cooling water pipes 13 and 14, and the shell-tube evaporator 10 is a cold water demand source such as a cooling coil. When connected to the cold water pipe (15, 16) (not shown), the cooling water condenses the refrigerant in the shell-tube condenser 6, the cold water evaporates the refrigerant in the shell-tube evaporator 10, shell-tube type Cold water evaporated refrigerant in the evaporator 10 may be composed of a chiller (Chiller) used in the cold water demand destination. Hereinafter, the shell-tube condenser 6 is connected to the cooling tower (not shown) and the cooling water flow path 13 and 14, and the shell-tube evaporator 10 is connected to the cold water demand and the cold water flow path 15 and 16. Explain.

Compressor (2) is the refrigerant evaporated in the shell-tube evaporator 10 is compressed, may be composed of one of a rotary compressor, a scroll compressor, a screw compressor, may be configured to vary the operating capacity, the refrigerant It can be configured to compress in multiple stages.

The compressor 2 includes a compression unit having a compression chamber in which a refrigerant is compressed, and a motor unit in which the compression unit provides a driving force for compressing the refrigerant.

The compressor 2 is filled with oil for preventing damage to the motor portion and the compression portion therein, the oil is discharged together with the refrigerant during the discharge of the refrigerant.

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

The refrigeration cycle device having a shell-tube condenser has no oil separator 4 installed in the shell-tube condenser 6, so that no separate oil separator is installed in the discharge pipe 20 or the oil separator 4 is shelled. A smaller oil separator can be installed if it is not built into the tubular condenser 6. Hereinafter, a description will be given when a separate oil separator is not installed in the discharge pipe 20, and the discharge pipe 20 may have one end connected to the compressor 2 and the other end connected to the shell-tube type condenser 6. .

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

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

 The shell-tube condenser 6 includes a shell 28 having an inlet 24 through which a coolant and an oil are introduced, and an outlet 26 through which the coolant flows out; It may include an inner tube 30 disposed inside the shell 28 and through which the fluid for condensing the refrigerant passes.

The shell 28 may have a discharge pipe 20 connected to the inlet 24, and an expander connection pipe 22 may be connected to the outlet 26.

The shell 28 has a condensation space in which the refrigerant is condensed as the heat exchanges with the inner tube 30, and the condensation space may be formed long in the longitudinal direction of the shell 28.

The inner tube 30 may be disposed in the shell 28 in the longitudinal direction of the shell 28, and may be connected to the coolant pipes 13 and 14, and the fluid passing through the inner tube 30 may be coolant. Cooling water introduced through the pipes 13 and 14 may be used.

The oil separator 4 includes an oil collecting plate 32 installed between the inlet 24 and the inner tube 30 to collect oil from the refrigerant and oil passing through the inlet 24; An oil tube 34 for guiding the oil collected on the oil collecting plate 32.

The oil collecting plate 32 may function as an anti-collision plate that prevents the refrigerant and oil passing through the inlet 24 from directly colliding with the inner tube 30, and the oil and the oil in the oil collecting plate 32 may be transferred to the oil collecting plate 32. It is configured to flow into the oil tube 34 after it is collected.

That is, the refrigerant and the oil passing through the inlet 24 collide with the oil collecting plate 32 at the lower position of the inlet 24, and the liquid oil is the oil tube 34 along the oil collecting plate 32. The refrigerant flowing in the gaseous phase hits the oil collecting plate 32 and then flows between the oil collecting plate 32 and the shell 28 and heat exchanges with the inner tube 30 inside the shell 28.

  The oil collecting plate 32 is installed at the lower position of the inlet 24 so as to face the inlet 24, and the area of the oil collecting plate 32 is larger than that of the inlet 24.

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

The expander 8 is to expand the refrigerant condensed in the shell-tube condenser 6, it may be made of a capillary tube or electronic expansion valves (EEV).

The shell-tube evaporator 10 is connected to the expander 8 and the expander connecting pipe 36.

The shell-tube type evaporator 10 includes a shell 42 having an inlet 38 through which a refrigerant flows in and an outlet 40 through which the refrigerant flows out, and an inner through which a fluid disposed inside the shell 42 and evaporating the refrigerant passes. It may include a tube 44.

The shell 42 may be connected to the inflator connecting pipe 36 to the inlet 38, the suction pipe 18 may be connected to the outlet 40.

The shell 42 has an evaporation space in which the refrigerant evaporates as the heat exchanges with the inner tube 44, 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, may be connected to the cold water pipes 15 and 16, and the fluid passing through the inner tube 44 may be cold water. Cold water introduced through the pipes 15 and 16 may be used.

The ejector mechanism 12 allows oil in the shell-tube condenser 6 to be recovered to the compressor 2 by bypassing the expander 8 and the shell-tube evaporator 10, as well as within the shell-tube evaporator 10. Oil may be recovered to compressor 2 by bypassing outlet 40 of shell-tube evaporator 10.

The ejector mechanism 12 may include an ejector 54 having a main flow path 50 and a joining 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 joining flow passage 52 when the fluid passes through a narrow portion of the main flow passage 50, and the overall shape is formed in a “T” shape. Can be.

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

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

The ejector mechanism 12 has an ejector discharge passage 58 having a main passage 50 and a suction pipe 18 so that refrigerant and oil passing through the main passage 50 are sucked into the compressor 2 through the suction pipe 18. It is possible to be connected to the, it is possible that the ejector discharge flow path 58 is connected to the main flow path 50 and the compressor 2 so that the refrigerant and oil passing through the main flow path 50 is directly sucked into the compressor (2). .

The ejector mechanism 12 has an ejector suction flow path 60 connected to one of the shell 28 of the shell-tube condenser 6 and one of the discharge pipe 20 and the oil tube 34 and connected to the main flow path 50. The other end may be connected.

When the ejector suction flow path 60 has one end connected to the discharge pipe 20 and the other end connected to the main flow path 50, the ejector mechanism 12 transfers oil from the oil tube 34 to the ejector suction flow path 60 or the main. It may further include an oil guide flow path (not shown) for guiding to the flow path 50, the oil and refrigerant and the oil tube flowed from the discharge pipe 20 to the main flow path 50 through the ejector suction flow path 60 ( The oil and refrigerant flowing into the main flow path 50 through the oil guide flow path 34 in 34 are used to generate the driving force of the ejector 54.

When the ejector suction flow path 60 can be connected at one end to the shell 28 of the shell-tube type condenser 6 and the other end to the main flow path 50, the ejector mechanism 12 is connected to the oil of the oil tube 34. It may further include an oil guide flow path (not shown) for guiding to the ejector suction flow path 60 or the main flow path 50, the ejector suction flow path 60 in the shell 28 of the shell-tube condenser 6 The refrigerant flowing through the main flow path 50 and the oil and refrigerant flowing through the oil guiding flow path from the oil tube 34 to the main flow path 50 are used to generate the driving force of the ejector 54.

The ejector suction flow path 60 may have one end connected to the oil tube 34 and the other end connected to the main flow path 50, and may flow from the oil tube 34 to the main flow path 50 through the ejector suction flow path 60. Oil and refrigerant are used to generate the driving force of the ejector (54).

When the ejector suction flow path 60 is connected to the oil tube 34, the ejector mechanism 12 does not need a separate oil guide flow path and is simple in structure, so that the ejector suction flow path 60 is connected to the oil tube 34. It is preferable.

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

First, when the compressor 2 is driven, the compressor 2 discharges gaseous refrigerant of high temperature and high pressure, and at this time, the oil in the compressor 2 is discharged into the discharge pipe 20 together with the gaseous refrigerant of high temperature and high pressure.

The refrigerant and oil discharged into the discharge pipe 20 are introduced into the shell 28 of the shell-tube condenser 6 through the inlet 24 of the shell-tube condenser 6. The refrigerant and oil introduced into the shell 28 collide with the oil collecting plate 32 first. The liquid oil of the refrigerant and the oil is partially collected in the oil collecting plate 32 and flows into the oil tube 34, and the rest flows into the lower portion inside the shell 28 of the shell-tube condenser 6. In addition, a portion of the refrigerant flows through the oil collecting plate 32 to the oil tube 34, and the rest flows between the oil collecting plate 32 and the shell 28, and then the inner tube 30 inside the shell 28. Heat exchanges with and condenses.

The oil flowing into the bottom of the shell 28 of the shell-tube condenser 6 and the liquid refrigerant condensed inside the shell 28 flow through the outlet 26 to the expander 8 and into the expander 8. The refrigerant flowing with the oil expands as it passes through the expander 8 and flows with the oil to the shell-tube evaporator 10.

The refrigerant and oil flowing into the shell-tube evaporator 10 flow into the shell 42 of the shell-tube evaporator 10, and the refrigerant among the refrigerant and oil flows inside the shell 42 of the shell-tube evaporator 10. Heat exchanges with the inner tube 44 to evaporate, and oil remains in the evaporator 10. The refrigerant evaporated while being heat-exchanged 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 passage 60 and pass through the main passage 50 of the ejector 54. When the refrigerant and the oil pass through the main flow passage 50 of the ejector 54, a suction force is generated in the confluence flow passage 52 of the ejector 54, and the oil of the shell-tube evaporator 10 is the evaporator oil recovery flow passage 56. Is sucked into the joining flow path 52 through The oil sucked into the confluence flow path 52 is mixed with the refrigerant flowing through the main flow path 50 and the oil, and then passed through the ejector discharge flow path 58 to be recovered to the compressor 2.

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

The oil collecting plate 32 shown in FIGS. 2 and 3 may include a mesh 70 and a holder 72 to which the mesh 70 is fixed and the oil tube 34 is connected.

The fixing stand 72 may be formed so that the upper and lower surfaces are open, and the upper surface and the lower surface may be formed to be blocked.

When both the upper and lower surfaces of the holder 72 are opened, the oil introduced into the inlet 24 is caught by the mesh 70 while colliding with the mesh 70, flowing along the mesh 70, and flowing into the inlet 24. The refrigerant may pass through the mesh 70 while colliding with the mesh 70, and then flow through the lower surface of the oil collecting plate 32 to flow below the oil collecting plate 32.

When the upper surface of the holder 72 is opened and the lower surface of the holder 72 is blocked by the lower plate, the oil introduced into the inlet 24 is caught by the mesh 70 while colliding with the mesh 70, thereby closing the mesh 70. Flowing along, the refrigerant flowing into the inlet 24 passes through the mesh 70 while colliding with the mesh 70, and then impinges on the lower plate of the oil collecting plate 32, and then passes through the upper surface of the holder 72 again. It may flow between 72 and shell 28.

When the upper surface of the holder 72 is open and the lower surface of the holder 72 is blocked, the oil collecting plate 32 is separated from the mesh 70 to the oil tube 34 along the lower plate of the holder 72. It can flow and can be dispersed widely after the refrigerant impinges on the lower plate of the holder 72.

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

When the bottom surface of the holder 72 is blocked, the oil collecting plate 32 may have an inclined flow path inclined downward toward the oil tube 34 so that the oil may flow into the oil tube 34 along the inclined flow path.

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

The oil collecting plate 32 shown in FIGS. 4 and 5 has a hole 80 formed in the upper plate, an oil flow path 82 through which oil is guided, and an oil tube 34 is formed in the oil flow path 82. It may include a communication box body 84, the configuration and operation other than the oil collecting plate 32 is the same or similar to the shell-tube type condenser first embodiment according to the present invention, detailed description thereof will be omitted. .

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

It is preferable that the area of the box body 84 is larger than that of the inlet port 24, and the lower surface and the circumferential surface are formed to be clogged so that oil introduced into the box body 84 is not leaked to the periphery of the box body 84. And flows along the oil passage 82 to the oil tube 34.

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

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

In the shell-tube type condenser according to the present embodiment, the refrigerant and the oil passing through the inlet 24 hit the upper plate of the box body 84, and at this time, the oil passes through the hole 80 and the inside of the box body 84. After flowing in, it flows through the oil passage 82 to the oil tube 34.

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

The oil collecting plate 32 shown in Figs. 6 and 7 has a hole 90 formed larger than the inlet 24, and other constructions and functions other than the hole 90 have a shell-tube type condenser according to the present invention. Since the same or similar to the embodiment, a detailed description thereof will be omitted.

That is, the oil collecting plate 32 has a hole 90 formed in the upper plate larger than the inlet 24, and an oil flow path 82 through which oil is guided is formed, and the oil tube 34 is disposed in the oil flow path 82. It may include a box body 84 in communication.

In the shell-tube type condenser according to the present embodiment, the refrigerant and oil passing through the inlet port 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 to be collected in the oil channel 82, and flows along the oil channel 82 to the oil tube 34. In addition, the refrigerant introduced into the box body 84 passes through the hole 90 again after colliding with the lower plate of the box body 84, and may flow between the box body 84 and the shell 28. .

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

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 toward the lower side, and the shell 100 according to the present invention has a structure and action other than the hole 100. The tubular condenser is the same as or similar to the second embodiment, and detailed description thereof will be omitted.

That is, the oil collecting plate 32 has a hole 100 having a trapezoidal cross-sectional shape in the upper plate, an oil passage 82 through which oil is guided, and an oil tube 34 communicating with the oil passage 82. The box body 84 may be included.

 The oil collecting plate 32 may form a hole 100 and the protrusions 102 opened in the vertical direction may protrude toward the inside of the box body 84, and the protrusions 102 may have an opening area toward the lower side. This can be made small.

In the shell-tube type condenser according to the present embodiment, the refrigerant and oil passing through the inlet port 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 to be collected in the oil channel 82, and flows along the oil channel 82 to the oil tube 34. Meanwhile, some of the oil collided with the lower plate of the box body 84 may flow toward the hole 100, but is blocked by the protrusion 102 and splashed upward of the box body 84 is minimized.

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

10 and 11, the oil collecting plate 32 has a grill 110 formed on the upper plate, an oil flow path 82 through which oil is guided, and an oil tube 34 is formed on the oil flow path 82. It may include a communicating box body 84, the configuration and operation other than the oil collecting plate 32 is the same or similar to the second embodiment of the shell-tube condenser according to the present invention, detailed description thereof will be omitted. .

The grill 110 may function to disperse the refrigerant and the oil introduced through the inlet 24, and the cross-sectional shape is formed to be round, so that the oil in the oil flow path 82 passes through the gap between the grills 110. Splashing to the upper side of the box body 84 can be minimized.

2: compressor 4: oil separator
6: shell-tube condenser 8: inflator
10 shell-tube evaporator 12 ejector apparatus
24: inlet 26: outlet
28: shell 30: inner tube
32: oil collector 34: oil tube
50: main euro 52: confluence euro
54: ejector 56: evaporator oil recovery flow path
58: ejector discharge flow path 60: ejector suction flow path
70: mesh 72: holder
80: hole 82: oil path
84: box 90: hole
100: hole 110: grill

Claims (20)

A shell having an inlet through which a coolant and an oil flow in the upper portion and an outlet through which the coolant flows out;
An inner tube disposed inside the shell and through which fluid condensing the refrigerant passes;
An oil collecting plate installed between the inlet and the inner tube and collecting oil from the refrigerant and oil passing through the inlet;
Shell-tube type condenser comprising an oil tube for guiding the oil collected on the oil collecting plate. The method of claim 1,
And said oil collecting plate comprises a mesh and a holder to which said mesh is fixed and to which said oil tube is connected. The method of claim 1,
The oil collecting plate is a shell-tube type condenser including a box body is formed in the upper plate and the oil passage through which the oil is guided and the oil tube communicates with the oil passage. The method of claim 3, wherein
The hole is a shell-tube condenser formed with a plurality of spaced apart. The method of claim 3, wherein
And the hole is formed larger than the inlet. The method of claim 3, wherein
The hole is a shell-tube condenser formed in a trapezoidal cross-sectional shape is reduced in area toward the lower side. The method of claim 1,
The oil collecting plate is a shell-tube type condenser having a grill body is formed on the upper plate and the oil flow path is formed therein and the oil tube is in communication with the oil passage. 8. The method according to any one of claims 2 to 7,
And the oil passage has a sloped passage inclined downward toward the oil tube. The method of claim 1,
The oil collection plate is installed inclined downwardly toward the oil tube. A compressor for compressing the refrigerant,
A shell-tube type condenser in which the refrigerant compressed in the compressor is condensed and the oil separator is built in,
An expander for expanding the refrigerant condensed in the shell-tube condenser;
A shell-tube evaporator for evaporating the refrigerant expanded in the expander;
An ejector mechanism for returning oil of the shell-tube condenser and oil of the shell-tube evaporator to the compressor,
The shell-tube condenser has a shell formed with an inlet through which a refrigerant and an oil flow in the upper portion, and an outlet through which the refrigerant flows out in the lower portion; An inner tube disposed inside the shell and through which fluid condensing the refrigerant passes;
The oil separator is installed between the inlet and the inner tube, and the oil collecting plate for collecting oil from the refrigerant and oil passing through the inlet; And a shell-tube type condenser comprising an oil tube for guiding oil collected on the oil collecting plate to the ejector mechanism. 11. The method of claim 10,
The ejector mechanism includes: an ejector having a main flow path and a joining flow path connected to the main flow path;
A suction pipe connecting the compressor and the shell-tube evaporator, and an ejector discharge flow path connecting one of the compressors and the main flow path;
An evaporator oil recovery passage connecting the confluence passage and the shell-tube evaporator;
And a shell-tube type condenser comprising an ejector suction passage connecting the oil tube and the main passage. The method of claim 10 or 11,
And the oil collection plate has a mesh and a shell-tubular condenser comprising a holder to which the mesh is fixed and to which the oil tube is connected. The method of claim 10 or 11,
The oil collecting plate is a refrigeration cycle apparatus having a shell-tube type condenser having a hole formed in the upper plate and the oil flow path is guided therein and the oil tube is in communication with the oil passage. The method of claim 13,
And the oil passage has a shell-tube type condenser having an inclined passage inclined downward toward the oil tube. The method of claim 13,
The hole is a refrigeration cycle apparatus having a plurality of shell-tube condenser formed spaced apart. The method of claim 13,
And said hole has a shell-tube condenser formed larger than said inlet. The method of claim 13,
The hole is a refrigeration cycle apparatus having a shell-tube type condenser formed in a trapezoidal cross-sectional shape is reduced in area toward the lower side. The method of claim 10 or 11,
The oil collecting plate is a refrigeration cycle apparatus having a shell-tube type condenser having a grill is formed on the top plate and an oil flow path is guided therein and the oil tube is in communication with the oil flow path. The method of claim 18,
And the oil passage has a shell-tube type condenser having an inclined passage inclined downward toward the oil tube. The method of claim 10 or 11,
And the oil collection plate has a shell-tube type condenser installed inclined downwardly toward the oil tube.

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