KR101606485B1 - Condenser - Google Patents

Abstract

The present invention relates to a condenser equipped with a receiver drier, which is constructed by a narrow and long oil discharge line formed by the outer surface of a sliding member inserted in the receiver dryer and floating on oil and liquid refrigerant and the inner wall of the receiver dryer tank The oil is discharged to the oil discharge hole formed in the oil discharge line through the capillary phenomenon in which the surface of the oil and the liquid coolant inside the oil discharge line becomes higher than the surface of the oil discharge line, And to reduce the residual amount of oil.

Description

Condenser

The present invention relates to a condenser equipped with a receiver drier, which is constructed by a narrow and long oil discharge line formed by the outer surface of a sliding member inserted in the receiver dryer and floating on oil and liquid refrigerant and the inner wall of the receiver dryer tank The oil is discharged to the oil discharge hole formed in the oil discharge line through the capillary phenomenon in which the surface of the oil and the liquid coolant inside the oil discharge line becomes higher than the surface of the oil discharge line, And to reduce the residual amount of oil.

The cooling system of the vehicle compresses the refrigerant, which performs heat exchange with the outside air, from the compressor to a high-temperature / high-pressure gas state and then sends it to a condenser. The condenser converts the gaseous refrigerant into a liquid state To the expansion valve. The expansion valve expands the refrigerant to a low-temperature / low-pressure state and sends it to an evaporator. The evaporator causes the low-temperature / low-pressure refrigerant to perform heat exchange with the indoor air of the vehicle to cool the interior of the vehicle.

In order for the refrigerant circulating through the above-mentioned path to absorb heat of the outside air, the refrigerant should be in a liquid state when it is condensed in the condenser, but a part of the refrigerant remains in a gaseous state and passes through the condenser.

Therefore, when the refrigerant in which the liquid phase and the vapor phase coexist is heat exchanged in the evaporator, the refrigerant in the gaseous state can hardly absorb the heat of the room air and thus the cooling efficiency is lowered.

In order to solve the above-mentioned problems, a receiver dryer is installed between a condenser and an expansion valve. The receiver dryer separates / removes gaseous refrigerant in the condenser, So that the cooling efficiency is increased.

Meanwhile, the compressor constituting the cooling device selectively receives the power of the engine through the pulley of the automobile by the intermittent action of the electromagnetic clutch, sucks and compresses the heat-exchanged refrigerant coming out of the evaporator, and discharges it to the condenser.

In order to smoothly drive the compressor, oil is contained in the refrigerant flowing therein, so that the oil is circulated to each part of the system together with the refrigerant during the operation of the system and lubricated.

However, when the oil flows into the heat exchanger such as the condenser, the expansion device, the pipe and the hose and is stagnated, the oil adheres to the inner surface of the heat exchanger or the like to reduce the heat exchange efficiency, occupies a predetermined space of the heat exchanger, In addition, since the amount of pressure drop of the refrigerant increases, adverse influences such as an increase in the driving load of the system are adversely affected.

In addition, since the lubricating oil is not sufficiently supplied to each driving part of the compressor, lubrication of the compressor can not be stably and smoothly performed, so that the durability of the compressor is deteriorated such that the driving parts are burned or the lock is generated.

The oil mixed in the refrigerant discharged from the compressor is mixed with the refrigerant flowing into the condenser and circulated in the condenser.

The refrigerant circulated in the condenser is introduced into the receiver drier. The receiver drier separates the gaseous refrigerant and the liquid refrigerant that are not completely liquefied in the condenser. The oil mixed in the liquid refrigerant at a specific temperature is separated from the liquid refrigerant And is separated on the liquid phase refrigerant by the density difference.

At this time, the liquid coolant that has settled in the lower end of the receiver drier is discharged through the discharge hole formed at the lower end of the outer surface of the receiver dryer, and is sent to the expansion valve. However, It is not smoothly discharged through the discharge hole and is stagnated inside the receiver dryer.

As the oil in the receiver dryer is stagnant and can not be returned to the compressor, the durability of the compressor is lowered and the efficiency of the cooling system is lowered as described above.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems as described above, and it is an object of the present invention to provide a refrigerator having a narrow width formed by an outer surface of a sliding member inserted in a receiver drier and floating on oil and liquid refrigerant, The oil is discharged to the oil discharge hole formed in the oil discharge line through the capillary phenomenon that the surface of the oil and the liquid coolant inside the oil discharge line becomes higher than the surface of the oil discharge line by the long oil discharge line, To prevent the oil from stagnating in the condenser, thereby reducing the residual amount of oil in the condenser and improving the heat exchange efficiency of the condenser.

It is another object of the present invention to provide a compressor in which oil introduced into a receiver drier is smoothly returned to a compressor without being left in the condenser, so that lubricating oil is sufficiently supplied to each driving part of the compressor to improve the durability of the compressor and the efficiency of the cooling system And a condenser.

The condenser of the present invention includes a first header tank (110) and a second header tank (120) spaced apart from each other by a predetermined distance. An inlet pipe 130 formed in the first header tank 110 or the second header tank 120 and through which the refrigerant flows and an outlet pipe 140 through which the refrigerant is discharged; A plurality of tubes 150 having both ends fixed to the first header tank 110 and the second header tank 120 to form refrigerant channels; A plurality of pins (160) interposed between the tubes (150 ) ; And a first header tank 110 and a second header tank 120. The first header tank 110 and the second header tank 120 are provided at one side of the first header tank 110 or the second header tank 120 to separate the gaseous refrigerant and the liquid refrigerant, 2 to communicate with the header tank 120 is formed in the hollow predetermined areas on the outer peripheral surface the receiver-drier tank 210, receiver-drier comprising a discharge hole 230, the coolant flows into the inlet hole 220 and the refrigerant is discharged to be ( 200) ; The receiver dryer 200 is installed between the inlet hole 220 and the outlet hole 230 in the longitudinal direction of the receiver dryer tank 210 and between the receiver dryer tank 210 and the receiver dryer tank 210. In the condenser 10, An oil discharge hole 240 formed in a predetermined area on the outer peripheral surface; A cylindrical flow path forming part 250 forming a flow path for the oil discharge hole 240 and the discharge hole 230 to communicate with each other outside the receiver dryer 200; An annular first blocking wall 271 which is located between the inflow hole 220 and the oil discharge hole 240 and protrudes toward the inside of the receiver dryer tank 210 on the inner circumferential surface of the receiver dryer tank 210, ); A cylindrical second blocking wall 272 extending in the longitudinal direction of the receiver dryer tank 210 toward the side where the discharge hole 230 is formed along the inner edge of the first blocking wall 271; And a cylindrical sliding member 260 inserted in the inner space of the second blocking wall 272 and slidable in the longitudinal direction of the receiver dryer tank 210 along the second blocking wall 272, ; And an inner edge of the first blocking wall 271 is connected to the receiver dryer tank 271 so that the upper surface of the sliding member 260 is not slid over the second blocking wall 272 in the direction in which the inflow hole 220 is formed. 210); And a condenser connected to the condenser.

The sliding member 260 is made of a material having a density lower than that of the oil and the liquid refrigerant so that the sliding member 260 can float on the oil and liquid refrigerant introduced into the receiver dryer tank 210.

At least one or more openings are formed in the lower surface of the sliding member 260 so that the oil and liquid refrigerant introduced into the sliding member 260 can be discharged to the outside of the sliding member 260 without stagnation. Is formed.

The second blocking wall 272 is disposed at a predetermined distance in parallel with the inner wall of the receiver dryer tank 210 so that oil flowing into the receiver dryer tank 210 flows into the oil drain hole 240, And is formed so as to be spaced apart.

The first blocking wall 271 is formed to be inclined inward of the receiver dryer tank 210 so that oil and liquid refrigerant flowing into the receiver dryer tank 210 can easily flow down in the gravity direction .

The present invention is characterized in that oil and liquid refrigerant in the oil discharge line are discharged by a narrow and long oil discharge line inserted into the receiver dryer and formed by the outer surface of the sliding member floating on the oil and liquid refrigerant and the inner wall of the receiver- The oil is discharged to the oil discharge hole formed on the inner wall of the receiver dryer tank of the oil discharge line through the capillary phenomenon that the surface of the oil discharge line is higher than the surface of the oil discharge line, And the heat exchange efficiency of the condenser can be improved.

Further, since the oil introduced into the receiver drier is smoothly conveyed to the compressor without being left in the condenser, lubricating oil is sufficiently supplied to each driving part of the compressor to improve the durability of the compressor and the efficiency of the cooling system There is an advantage.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a configuration diagram showing a refrigeration cycle of the present invention;
2 is a perspective view showing a condenser of the present invention.
3 is a partial cross-sectional view of the condenser of the present invention.
4 is a partial cross-sectional view illustrating the flow of refrigerant in the condenser of the present invention.
5 is a cross-sectional view of the receiver dryer of the condenser of the present invention.
6 is a cross-sectional view of a receiver drier of another condenser of the present invention.
7 is a view showing an oil discharge line whose length varies in accordance with the level of oil and liquid refrigerant in the receiver drier of the condenser of the present invention.

Hereinafter, a condenser of the present invention having the above-described characteristics will be described in detail with reference to the accompanying drawings.

2 is a perspective view of a condenser of the present invention, FIG. 3 is a partial sectional view of a condenser of the present invention, and FIG. 4 is a cross-sectional view of a condenser of the present invention, 6 is a cross-sectional view of a receiver drier of another condenser according to the present invention, and Fig. 7 is a cross-sectional view of a receiver drier of the condenser according to the present invention. Fig. And an oil discharge line whose length varies according to the level of the liquid coolant.

The condenser 10 shown in FIGS. 2 and 3 has a first header tank 110 and a second header tank 120 which are spaced apart from each other by a predetermined distance, and the first header tank 110 and the second header tank 120, The second header tank 120 is generally formed by the combination of the header 111 and the tank 112.

2 and 3, the condenser 10 is formed in the first header tank 110 or the second header tank 120 and includes an inlet pipe 130 through which refrigerant flows and an outlet pipe 140 through which the refrigerant is discharged. ).

In addition, the first header tank 110 and the second header tank 120 have a plurality of tubes 150, both ends of which are fixed to each other to form refrigerant flow paths, and are spaced apart from each other at regular intervals.

A plurality of fins 160 interposed between the tubes 150 and increasing a heat transfer area with air flowing between the tubes 150 has a maximum heat transfer area The pins 160 are bent upward and downward and interposed between the tubes 150. [

3, the first header tank 110 and the second header tank 120 include a plurality of baffles 170 for controlling the flow of refrigerant so that the refrigerant is moved in a staggered manner through the tubes 150. [ ) Are alternately arranged inside.

The condenser 10 is provided at one side of the first header tank 110 or the second header tank 120 and includes a receiver drier 170 for separating the gaseous refrigerant from the liquid refrigerant, Liquid refrigerant is sent to the upper end and the liquid-phase refrigerant is sent to the lower end, and finally the receiver-dryer 200 collects only the liquid-phase refrigerant, thereby inducing the supercooling angle.

The inlet pipe 130 and the outlet pipe 140 are provided in the first header tank 110 or the second header tank 120 so as to allow refrigerant to be introduced or discharged. When the receiver dryer 200 is installed adjacent to the second header tank 120 to communicate with the second header tank 120, the inlet pipe 130 and the outlet pipe 140 are connected to the receiver dryer 170, And is installed in the header tank 110.

The receiver dryer 200 includes a cylindrical receiver-dryer tank 210 and a plurality of first header tanks 110 and a plurality of second header tanks 120. The receiver- An inlet hole 220 through which the refrigerant flows, and a discharge hole 230 through which the refrigerant is discharged.

Particularly, the receiver drier 200 of the condenser 10 of the present invention includes the oil discharge hole 240, the flow passage forming part 250, the first blocking wall 271, the second blocking wall 272, Member 260 and height restricting portion 273 are further provided.

The oil discharge hole 240 is formed in the longitudinal direction of the receiver dryer tank 210 by hollowing the peripheral portion of the receiver dryer tank between the inlet hole 220 and the discharge hole 230.

The passage forming part 250 is cylindrical and the oil discharge hole 240 and the discharge hole 230 communicate with each other outside the receiver dryer 200 to form a flow path.

The first blocking wall 271 is annular and is positioned between the inlet hole 220 and the oil drain hole 240. The first blocking wall 271 is formed on the inner circumferential surface of the receiver dryer tank 210 in the longitudinal direction of the receiver dryer tank 210 As shown in Fig.

3 and 5, the second blocking wall 272 extends downward along the inner edge of the first blocking wall 271 in parallel with the inner wall of the receiver dryer tank 210 And is formed to be spaced apart from the inner wall of the receiver dryer tank 210 by a certain distance so that oil flowing into the receiver dryer tank 210 flows into the oil drain hole 240.

The sliding member 260 is inserted into the inner space of the second blocking wall 272 and is slidably moved along the second blocking wall 272 in the longitudinal direction of the receiver dryer tank 210, do.

The sliding member 260 is preferably made of a material having a density lower than that of the oil and the liquid refrigerant so that the sliding member 260 can always float on the oil and liquid refrigerant introduced into the receiver dryer tank 210.

At least one or more opening portions 261 are formed in the lower surface of the sliding member 260 so that oil and liquid refrigerant introduced into the sliding member 260 can be discharged out of the sliding member 260 without stagnation. And is formed in a hollow region.

The height restricting portion 273 is formed on the inner side of the first blocking wall 271 so that the upper surface of the sliding member 260 is not slid over the second blocking wall 272 in the direction in which the inflow hole 220 is formed And an edge is formed to protrude inward of the receiver dryer tank 210.

3 to 7, the sliding member 260 can be slid upward and downward by a predetermined distance from the inner wall of the receiver dryer tank 210 by the second blocking wall 272 The second blocking wall 272 and the oil draining passage varying in length due to the upward sliding movement of the sliding member 260 between the sliding member 260 and the inner wall of the receiver dryer tank 210, A line 270 is formed.

7 (a) is a view showing a state in which the level of the oil and liquid refrigerant is higher than the end of the second blocking wall 272, and Fig. 7 (b) ), Which indicates that the length of the oil discharge line 270 is fluidly changed according to the level of the oil and the liquid coolant.

The receiver dryer 200 has a capillary phenomenon in which the surface of the liquid inside the pipe becomes higher than the surface of the liquid in the inside of the pipe when a narrow and long pipe is inserted into the liquid, The surface of the oil is higher than the surfaces of the oil and liquid refrigerant outside the oil discharge line 270 and the oil is discharged through the oil discharge hole 240 along the oil discharge line 270.

Referring to FIG. 4, a refrigerant flow in the condenser 10 will be briefly described.

The gaseous refrigerant compressed by the compressor at high temperature and high pressure flows into the inlet pipe 130 of the first header tank 110 and is moved to the second header tank 120 by the baffle 170 provided therein. At this time, since the condensation occurs in the condenser 10, the gaseous phase and the liquid phase are mixed, so that the gaseous refrigerant is moved upward and the liquid refrigerant is moved downward.

The liquid refrigerant collected in the lower portion of the receiver dryer 200 through the upper and lower regions along the flow path formed by the baffle 170 collects most of the liquid refrigerant. When the liquid refrigerant passes through the subcooled region, The enthalpy of the refrigerant can be further lowered and the cooling efficiency can be increased.

The refrigerant passing through the upper and lower regions along the flow path formed by the baffle 170 flows into the receiver dryer 200 and is separated into the gas phase refrigerant and the liquid phase refrigerant in the receiver dryer 200, The liquid refrigerant is located at the lower end of the liquid refrigerant.

At this time, the oil contained in the refrigerant flowing into the receiver dryer (200) is separated into the upper layer and the liquid refrigerant located at the lower end of the receiver dryer (200).

As described above, when the density of oil is higher than that of the liquid refrigerant, the liquid refrigerant and the oil separated from the liquid refrigerant are returned through the discharge hole 230 formed adjacent to the lower end of the outer circumferential surface of the receiver dryer 200, The refrigerant passes through the outlet pipe 120 of the first header tank 110 and is returned to the compressor through the expansion valve and the evaporator.

On the other hand, when the density of the oil is lower than that of the liquid phase refrigerant, the oil floating on the liquid phase refrigerant is discharged to the oil discharge hole 240 through the oil discharge line 270 by capillary phenomenon, Is mixed with the liquid refrigerant discharged to the discharge hole (230) through the flow path forming part (250) formed to communicate the oil discharge hole (240) and the discharge hole (230) Cooled and passed through the outlet pipe 140 of the first header tank 110 to the compressor through the expansion valve and the evaporator.

Describing the method of manufacturing the condenser 10 of the present invention, each component to be used first is manufactured.

A header, a tube 150, a fin 160, and a receiver dryer 200, which form the first header tank 110 and the second header tank 120, One of the tank 110 and the second header tank 120 may be formed with a communicating hole 180 so that the receiver dryer 200 can be provided at one side thereof and may be formed of a material having a density lower than that of the oil and the refrigerant. The manufactured sliding member 260 is prepared.

The receiver dryer 200 is formed by extruding a cylindrical receiver dryer tank 210 and a tubular flow path forming part 250. The receiver dryer tank 210 and the flow path forming part 250 can be manufactured by various methods, but it is preferable to use the extrusion with the highest productivity.

The inlet hole 220, the discharge hole 230 and the oil discharge hole 240 communicating with the first header tank 110 or the second header tank 120 are cut on the outer circumferential surface of the receiver dryer tank 210, Lt; / RTI >

The sliding member 260 is inserted into the receiver dryer tank 210 in which the inlet hole 220, the discharge hole 230, the oil discharge hole 240 and the flow passage forming portion 250 are formed, do.

Next, the header 111, the tube 150 and the pin 160 assembly are formed to fix the header, the tube 150 and the pin 160 assembly, the tank, and finally the receiver dryer 200 Is fixed to one side to produce the condenser 10.

At this time, one side and the other side of the flow path forming part 250 are connected to the oil discharge hole 240 and the discharge hole 230, respectively, and are connected to each other. 250 are fixed.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

10: Condenser
110: first header tank
120: second header tank
130: inlet pipe
140: outlet pipe
150: tube
160: pin
170: Baffle
180: communication hole
200: Receiver dryer
210: Receiver dryer tank
220: inlet hole
230: discharge hole
240: Oil drain hole
250: flow path forming portion
260: sliding member 261: opening
270: Oil discharge line 271: First blocking wall
272: second blocking wall 273: height restricting portion

Claims (5)

A first header tank (110) and a second header tank (120) spaced apart from each other by a predetermined distance; An inlet pipe 130 formed in the first header tank 110 or the second header tank 120 and through which the refrigerant flows and an outlet pipe 140 through which the refrigerant is discharged; A plurality of tubes 150 having both ends fixed to the first header tank 110 and the second header tank 120 to form refrigerant channels; A plurality of pins (160) interposed between the tubes (150 ) ; And the first header tank 110 or the second header is provided at one side of the tank 120, gaseous refrigerant and liquid refrigerant separated, and a cylindrical receiver drier tank 210 a and the first header tank 110, or 2 to communicate with the header tank 120 is formed in the hollow predetermined areas on the outer peripheral surface the receiver-drier tank 210, receiver-drier comprising a discharge hole 230, the coolant flows into the inlet hole 220 and the refrigerant is discharged to be ( 200) ; And a condenser (10)
The receiver dryer (200)
An oil discharge hole 240 formed between the inflow hole 220 and the discharge hole 230 in the longitudinal direction of the receiver dryer tank 210 and hollowed in a predetermined area on the outer circumferential surface of the receiver dryer tank 210 ; A cylindrical flow path forming part 250 forming a flow path for the oil discharge hole 240 and the discharge hole 230 to communicate with each other outside the receiver dryer 200 ; An annular first blocking wall 271 which is located between the inflow hole 220 and the oil discharge hole 240 and protrudes toward the inside of the receiver dryer tank 210 on the inner circumferential surface of the receiver dryer tank 210, ); A cylindrical second blocking wall 272 extending in the longitudinal direction of the receiver dryer tank 210 toward the side where the discharge hole 230 is formed along the inner edge of the first blocking wall 271 ;
A cylindrical sliding member 260 inserted into the inner space of the second blocking wall 272 and slidable in the longitudinal direction of the receiver dryer tank 210 along the second blocking wall 272 and having an opened upper surface ; And
The inner edge of the first blocking wall 271 is connected to the receiver dryer tank 210 so that the upper surface of the sliding member 260 does not slide over the second blocking wall 272 in the direction in which the inlet hole 220 is formed. A height restricting portion 273 protruding inward from the inner side of the lower end portion ; And a condenser connected to the condenser.
The method according to claim 1,
The sliding member 260
And a material having a density lower than that of the oil and the liquid refrigerant so as to float on the oil and the liquid refrigerant flowing into the receiver dryer tank (210).
3. The method of claim 2,
The sliding member 260
At least one or more openings 261 are formed in a predetermined region of the lower surface of the sliding member 260 so that oil and liquid refrigerant introduced into the sliding member 260 can be discharged out of the sliding member 260 without stagnation. The condenser.
The method according to claim 1,
The second blocking wall (272)
Wherein the oil receiver hole is formed at a predetermined distance in parallel with an inner wall of the receiver dryer tank so that oil flowing into the receiver dryer tank is formed into a flow path to the oil drain hole.
5. The method of claim 4,
The first blocking wall 271
And the oil and liquid refrigerant flowing into the receiver dryer tank (210) are inclined inward of the receiver dryer tank (210) so that the oil and liquid refrigerant flow downward in the gravity direction.

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