KR102459106B1 - Receiver drier and condenser having the same - Google Patents

Abstract

The present invention relates to a gas-liquid separator and a condenser including the same, wherein a diaphragm dividing the inside of the gas-liquid separator of the condenser and a filter for removing foreign substances from a heat exchange medium are integrally formed so that the filter can serve as a diaphragm together, It relates to a gas-liquid separator and a condenser including the same, which can reduce the number of component parts, improve assembly, and reduce manufacturing cost by easy handling and management.

Description

Gas-liquid separator and condenser including same {Receiver drier and condenser having the same}

The present invention relates to a gas-liquid separator and a condenser including the same, and in a condenser having a sub-cool formed thereon and a gas-liquid separator included therein, by separating a gas-liquid refrigerant and a liquid refrigerant in the gas-liquid separator to obtain only a liquid refrigerant A gas-liquid separator that can flow into the supercooling part of the upper part of the condenser to improve the efficiency of the condenser, and can reduce the number of parts by simplifying the components of the gas-liquid separator, facilitate assembly, and reduce manufacturing costs, and a condenser including the same is about

A heat exchanger is a device that absorbs heat from one side and radiates heat to the other between two environments with a temperature difference. In some cases, it acts as a heating system. Basically, the heat exchanger consists of an evaporator that absorbs heat from the surroundings, a compressor that compresses a heat exchange medium, a condenser that discharges heat to the surroundings, and an expansion valve that expands the heat exchange medium.

In the cooling device, the actual cooling action occurs by the evaporator in which the liquid heat exchange medium absorbs heat equivalent to the heat of vaporization from the surroundings and is vaporized. The gaseous heat exchange medium flowing into the compressor from the evaporator is compressed at high temperature and high pressure in the compressor, and liquefaction heat is emitted to the surroundings while the compressed gaseous heat exchange medium is liquefied while passing through the condenser, and the liquefied heat exchange As the medium passes through the expansion valve again, it becomes in a low-temperature and low-pressure wet-saturated vapor state, and then flows back into the evaporator to vaporize, thereby forming a cycle.

As described above, in the condenser, a heat exchange medium in a gaseous state of high temperature and high pressure is introduced, condensed in a liquid state while discharging heat of liquefaction by heat exchange, and then discharged. A conventional condenser is shown in FIG. 1 .

In the condenser shown in FIG. 1, the gaseous refrigerant flows into the inlet pipe 11, passes through the lower condensation area 10 separated by the partition plate 12, is cooled, and is converted into a liquid refrigerant, and a first communication pipe ( 31) and flows into the gas-liquid separator 30, only the liquid refrigerant flows to the upper side of the diaphragm 33 through the filter 37 and the riser pipe 34, and passes through the second communication pipe 32 to the supercooling region 20 It has a structure in which the liquid refrigerant is supercooled while passing through and discharged to the outlet pipe 21 . Thus, the enthalpy of the heat exchange medium can be further lowered by the occurrence of supercooling, so that the cooling efficiency can be increased.

Here, in the conventional condenser as shown in FIG. 1 , the gas-liquid separator 30 is partitioned inside by a diaphragm 33 , and a gaseous refrigerant is provided on the upper side of the drying material 35 , which is the lower side of the diaphragm 33 . Only the liquid refrigerant flows to the lower part of the collected drying material 35 and flows to the upper side of the diaphragm 33 along the rising pipe 34 configured in the gas-liquid separator 30 to the supercooling region 20 above the condenser ), only the liquid refrigerant flows and is supercooled. At this time, for example, a protruding step is formed on the inner circumferential surface of the gas-liquid separator 30 so that the height at which the diaphragm 33 for partitioning the inside of the gas-liquid separator 30 is inserted downward is limited so that the diaphragm 33 is hooked. , a filter 40 having a mesh network 41 formed on the outer circumferential surface is inserted on the upper side of the diaphragm 33 , and a cap 50 is inserted on the upper side of the filter 40 , so that the cap 50 is the upper end of the gas-liquid separator 30 . By being coupled to the diaphragm 33, the filter 40 and the cap 50 can be fixed in close contact.

However, as described above, since the diaphragm 33, the filter 40 including the mesh network, and the cap 50 are separately formed and assembled in the gas-liquid separator 30, the number of parts increases, so assembling property is reduced, and manufacturing and management cost will increase. In addition, since the filter has a mesh network for removing foreign substances from the refrigerant formed on the outer circumferential surface of the body, there is a difficulty in managing and assembling parts due to the possibility of breakage.

JP 3925158 B2 (2007.03.09)

The present invention has been devised to solve the above-described problems, and an object of the present invention is to reduce the number of components by integrally forming a diaphragm dividing the inside of a gas-liquid separator of a condenser and a filter for removing foreign substances from a heat exchange medium. It is to provide a gas-liquid separator capable of reducing and a condenser including the same.

In addition, a mesh network is formed inside the body of the diaphragm integrated filter to provide a gas-liquid separator that is easy to assemble and handle, and a condenser including the same.

The gas-liquid separator 200 of the present invention for achieving the above object is formed as a tube with an open upper end and is disposed in the height direction, a refrigerant inlet hole 213 is formed on the lower side, and a refrigerant outlet hole ( a housing 210 in which 214 is formed; It is inserted into the housing 210 and coupled to the housing 210 to be disposed below the refrigerant discharge hole 214 , and a space is formed in the body 221 to communicate with the space at the lower side of the refrigerant inlet. (222) is formed, the refrigerant outlet (224) is formed on the upper side, is provided in the space portion, the filter medium (225) is installed between the refrigerant inlet (222) and the refrigerant outlet (224) (220); a cap 230 coupled to the open upper end of the housing 210 and having a lower end in close contact with or coupled to the filter 220; and a rising pipe 240 having an upper end coupled to and connected to the refrigerant inlet 222 of the filter 220 and having a lower end disposed inside the housing 210; It is characterized in that it comprises a.

In addition, the housing 210 has a stepped 211 protruding from the lower inner circumferential surface of the refrigerant discharge hole 214 , and the filter 220 has a protruding hook 228 on the outer circumferential surface, the locking jaw (228) is characterized in that it is coupled to be caught on the stepped (211).

In addition, the cap 230 has a body 231 coupled to the housing so that the lower surface of the body 231 is located above the refrigerant discharge hole 214 of the housing 210 , and moves downward from the lower surface of the body 231 . The close contact protrusion 232 is extended so that the lower end of the close contact protrusion 232 is coupled to the upper surface of the filter 220 so that the outer diameter of the close contact protrusion 232 is greater than the outer diameter of the filter 220 body 221 . It is characterized in that it is formed small.

In addition, the filter medium 225 of the filter 220 is formed in the form of a plate or a membrane to partition the inner space of the body 221 and is coupled to the body 221 .

In addition, the filter 220 is characterized in that the body 221 and the filter medium 225 are integrally formed by insert injection.

In addition, the filter 220 has a recessed seating groove 226 formed on the outer circumferential surface of the body 221 in the circumferential direction so that the second sealing member 227 is inserted into the seating groove 226, the seating groove ( 226 is characterized in that it is formed on the upper side of the locking jaw (228).

In addition, the filter 220 has a recessed seating groove 226 formed on the outer circumferential surface of the body 221 in the circumferential direction so that the second sealing member 227 is inserted into the seating groove 226, the seating groove ( 226) is formed on the lower side of the locking step 228, the upper side of the step 211 is characterized in that the inclined surface 212 is formed to be inclined toward the inner lower side.

In addition, the filter 220 is characterized in that the guide tube 223 is formed extending from the refrigerant inlet 222, the riser tube 240 is fitted to the guide tube 223 is coupled.

And the condenser 1000 of the present invention, a pair of header tanks 100 are spaced apart from each other and formed side by side; an inlet pipe 110 and an outlet pipe 120 formed in the one side of the header tank 100 to allow a heat exchange medium to flow in or out; a plurality of baffles 130 provided inside the header tank 100 to control the flow of a heat exchange medium; a plurality of tubes 160 having both ends fixed to the pair of header tanks 100 to form a flow path of a heat exchange medium; a fin 170 interposed between the tubes 160; and the gas-liquid separator 200 provided on the other side of the header tank 100 to separate the gas-phase heat exchange medium and the liquid-phase heat exchange medium; The header tank 100 and the tube 170 are partitioned by the baffle 130 to form a condensation area A1 at the lower portion and a subcooling area A2 at the upper portion, so that the gas-liquid The refrigerant inlet hole 213 of the separator 200 is connected to the condensing area A1 through the lower communication pipe 140, and the refrigerant discharge hole 214 is connected to the supercooling area A2 through the upper communication pipe 150. do.

The gas-liquid separator of the present invention and the condenser including the same are integrally formed with a diaphragm partitioning the inside of the gas-liquid separator and a filter for removing foreign substances from the heat exchange medium, so that the number of components can be reduced, so that assemblyability is improved, handling and management It has the advantage of being easy to use and thus reducing the manufacturing cost.

1 is a cross-sectional schematic view showing a conventional gas-liquid separator and condenser.
2 and 3 are an assembled perspective view and a front schematic view showing a gas-liquid separator of the present invention and a condenser including the same.
Figure 4 is a cross-sectional perspective view showing the gas-liquid separator of the present invention.
5 is a cross-sectional perspective view showing a filter and a cap according to the present invention.
6 and 7 are partial cross-sectional views showing first and second embodiments of a housing and a filter according to the present invention.

Hereinafter, the gas-liquid separator of the present invention having the configuration as described above and the condenser including the same will be described in detail with reference to the accompanying drawings.

2 and 3 are an assembled perspective view and a front schematic view showing a gas-liquid separator of the present invention and a condenser including the same, FIG. 4 is a cross-sectional perspective view showing a gas-liquid separator of the present invention, and FIG. 5 is a filter and a cap according to the present invention 6 and 7 are partial cross-sectional views showing the first and second embodiments of the housing and filter according to the present invention.

As shown, the gas-liquid separator 200 of the present invention is formed of a tube with an open upper end and is disposed in the height direction, a refrigerant inlet hole 213 is formed on the lower side, and a refrigerant outlet hole 214 is formed on the upper side. housing 210; It is inserted into the housing 210 and coupled to the housing 210 to be disposed below the refrigerant discharge hole 214 , and a space is formed in the body 221 to communicate with the space at the lower side of the refrigerant inlet. (222) is formed, the refrigerant outlet (224) is formed on the upper side, is provided in the space portion, the filter medium (225) is installed between the refrigerant inlet (222) and the refrigerant outlet (224) (220); a cap 230 coupled to the open upper end of the housing 210 and having a lower end in close contact with or coupled to the filter 220; and a rising pipe 240 having an upper end coupled to and connected to the refrigerant inlet 222 of the filter 220 and having a lower end disposed inside the housing 210; may be included.

First, the gas-liquid separator 200 of the present invention may be largely composed of a housing 210 , a filter 220 , a cap 230 , and a riser 240 .

The housing 210 may be formed as a hollow tube inside, and may be formed to be elongated in the vertical direction, and may have an open top. And the lower end may be formed to be closed, and the housing 210 may be formed so that the lower end is closed by combining a separate blocking plate with the lower end of the tube having the upper end and the lower end open. In addition, the housing 210 may have a refrigerant inlet hole 213 through which a heat exchange medium is introduced at a lower side and a refrigerant discharge hole 214 through which a heat exchange medium is discharged at an upper side of the housing 210 .

The filter 220 may be formed to include a body 221 and a filter medium 225 . The body 221 may be formed in the form of a hollow chamber, and thus a space may be formed therein. And the refrigerant inlet 222 may be formed at the lower side of the body 221 to communicate with the space, and the refrigerant outlet 224 may be formed at the upper side to communicate with the space. In addition, a filter medium 225 for filtering foreign substances in the heat exchange medium is provided in the space portion, and the filter medium 225 is disposed between the refrigerant inlet 222 and the refrigerant outlet 224 to be coupled to the body 221 . can be installed. Here, in the filter 220 , the filter 220 may be inserted into the housing 210 so that the outer circumferential surface of the body 221 is in close contact with or close to the inner circumferential surface of the housing 210 . In this case, the filter 220 may be inserted from the top to the bottom through the open top of the housing 210 to be coupled to be disposed inside the housing 210 . In addition, the filter 220 may be disposed such that the upper end of the body 221 is located lower than the refrigerant discharge hole 214 of the housing 210 in the height direction. Thus, as the filter 220 is inserted into the housing 210 and coupled, the inner space of the housing 210 may be divided into an upper side and a lower side by the filter 220 . That is, in order for the heat exchange medium to flow from the lower side partitioned by the filter 220 to the upper side, it may be configured to pass through the refrigerant inlet 222, the filter medium 225, and the refrigerant outlet 224 of the filter 220 in order. have. In this case, the filter medium 225 may be a mesh network capable of filtering foreign substances from the heat exchange medium, and may be formed in various ways to filter foreign substances in a solid state included in the liquid heat exchange medium.

The cap 230 is coupled to the open top of the housing 210 , and the open top of the housing 210 may be sealed by the cap 230 . In addition, the cap 230 may be formed such that the lower side is coupled to be inserted into the housing 210 and the upper side is hooked on the housing 210 . At this time, the lower end of the cap 230 may be fixed by pressing the filter 220 by being in close contact with the upper surface of the filter 220 , and the lower end of the cap 230 may be coupled to the upper surface of the filter 220 and the filter 220 . may be fixed.

The riser pipe 240 is a pipe formed so that the heat exchange medium flows, and is formed of a pipe with both ends open and is elongated in the vertical direction, and the upper end may be coupled to the refrigerant inlet 222 of the filter 220 . Thus, the upper end of the riser tube 240 is connected to the refrigerant inlet 222 of the filter 220 , and the lower end of the riser tube 240 is disposed below the housing 210 to rise from the blocked lower end of the housing 210 . The lower end of the tube 240 may be disposed to be spaced apart from each other by a predetermined distance.

In addition, a drying material 250 may be provided on one side of the riser 240 in a portion of the housing 210 and spaced apart from the lower side of the filter 220 , and the drying material 250 contained in the heat exchange medium Moisture can be removed.

Thus, the gaseous (gas phase) heat exchange medium among the heat exchange media introduced into the inner lower side of the housing 210 through the refrigerant inlet hole 213 formed at the lower side of the housing 210 floats upward by the buoyancy force and is then removed by the filter 220. It is blocked by the partitioned portion and collected at the lower side of the filter 220 , and only the heat exchange medium in a liquid state (liquid state) flows upward along the riser 240 and may be introduced into the filter 220 . At this time, the heat exchange medium introduced through the refrigerant inlet 222 penetrating up and down on the lower surface of the body 221 of the filter 220 passes through the filter medium 225 inside the body 221 of the filter 220 to remove foreign substances. After being removed, it is configured to be discharged through the refrigerant outlet 224 formed vertically through the upper surface of the body 221 through the upper side of the housing 210 through the refrigerant discharge hole 214 formed on the upper side of the housing 210 can

Accordingly, the gas-liquid separator of the present invention is formed as a diaphragm-integrated filter so that the filter for removing foreign substances from the heat exchange medium can play the role of a diaphragm dividing the interior of the housing into an upper side and a lower side. As a result, assembling property is improved and handling and management are easy, thereby reducing manufacturing cost.

In addition, the housing 210 has a stepped 211 protruding from the lower inner circumferential surface of the refrigerant discharge hole 214 , and the filter 220 has a protruding hook 228 on the outer circumferential surface, the locking jaw (228) may be coupled to be caught on the step (211).

That is, the filter 220 is inserted into and coupled to the inside of the housing 210 as shown, but the stepped 211 is formed to protrude from the inner circumferential surface of the housing 210 and the engaging protrusion 228 is formed on the outer circumferential surface of the filter 220 . ) is formed to protrude, so that the engaging projection 228 of the filter 220 is engaged with the stepped 211 so that the height (depth) at which the filter 220 is inserted into the housing 210 can be limited, so that the filter 220 ) can be placed and fixed at the correct height. At this time, the upper surface of the step 211 and the lower surface of the locking jaw 228 may be formed to be in close contact with each other.

In addition, the cap 230 has a body 231 coupled to the housing 210 so that the lower surface of the body 231 is located above the refrigerant discharge hole 214 of the housing 210 , and the lower surface of the body 231 . A close contact protrusion 232 is formed extending downward from the lower end of the close contact protrusion 232 is coupled to the upper surface of the filter 220, the outer diameter of the close contact protrusion 232 is the filter 220 body (221) It can be formed smaller than the outer diameter of.

That is, the cap 230 has a body 231 formed on the upper side and a contact protrusion 232 extending downward from the lower surface of the body 231 , and the outer diameter of the contact protrusion 232 is the outer diameter of the body 231 and The filter 220 may be formed smaller than the outer diameter of the body 221 . In addition, the body 231 of the cap 230 may be coupled to the housing 210 such that the lower surface of the body 231 is disposed above the refrigerant discharge hole 214 formed in the housing 210 . The lower end of the contact protrusion 232 formed extending downward from the lower surface may be in close contact with the upper surface of the filter 220 body 221 . At this time, a female thread is formed on the inner peripheral surface of the upper end of the housing 210 , and a male thread 235 is formed on the outer peripheral surface of the body 231 , so that the body 231 can be screwed to the housing 210 , and the cap 230 . ) is screwed to the housing 210, the contact protrusion 232 presses the filter 220 in the downward direction, and the contact surface of the engaging jaw 228 of the filter 220 and the step 211 of the housing 210 can be in close contact. have. In addition, the force of the cap 230 to be in close contact with the housing 210 may be adjusted according to the degree to which it is screwed.

Therefore, since an empty space is formed in the peripheral portion of the close contact protrusion 232 of the cap 230 , the heat exchange medium discharged through the refrigerant outlet 224 on the upper side of the filter 220 through this space is discharged into the empty space around the close contact protrusion 232 . It may be discharged to the refrigerant discharge hole 214 of the housing 210 through the space. And in this case, the contact protrusion 232 may be formed or disposed in various shapes and numbers, and as an example, one contact protrusion may be formed in a cylindrical shape disposed coaxially with the central axis of the cap 230 . have. Alternatively, the close contact protrusions 232 may be formed in a trapezoidal cone shape whose cross-sectional area becomes smaller toward the lower side, or a plurality of close contact protrusions may be formed to be spaced apart from each other in a circular arrangement.

In addition, the filter medium 225 of the filter 220 may be formed in the form of a plate or a membrane to partition the inner space of the body 221 to be coupled to the body 221 .

That is, as illustrated, the filter medium 225 may be formed to have a thin thickness, such as a plate or a membrane, and may be coupled to the body 221 to partition the internal space of the body 221 . At this time, the filter medium 225 may be formed in the vertical direction, so that the refrigerant inlet 222 and the refrigerant outlet 224 may be formed on opposite sides of the filter medium 225 . Alternatively, the filter medium 225 may be formed in a horizontal direction or a diagonal direction, and may be arranged in various forms to partition the refrigerant inlet 222 and the refrigerant outlet 224 . Alternatively, the filter medium may be formed in a block shape, not a plate shape, and may be provided in a form filled with the inside of the body 221 , or the filter medium may be formed in various ways such as a porous block.

In addition, the filter 220 may be formed integrally with the body 221 and the filter medium 225 by insert injection.

That is, the body 221 and the filter medium 225 are integrally formed, and after inserting the filter medium 225 during injection molding, the shape of the body 221 is injected with a resin material, etc. The filter 220 may be formed integrally by insert-injecting provided in the combined form. Thus, the filter medium 225 is provided inside the body 221 and a structure for coupling can be formed very simply, and the body 221 can be formed as a single unit rather than a separate type. The possibility that the heat exchange medium may leak from the inside to the outside can be completely eliminated.

In addition, the filter 220 has a recessed seating groove 226 formed on the outer circumferential surface of the body 221 in the circumferential direction so that the second sealing member 227 is inserted into the seating groove 226, the seating groove ( 226 may be formed on the upper side of the stopping protrusion 228 .

That is, referring to FIG. 6 , a seating groove 226 is formed concavely along the circumferential direction on the outer circumferential surface of the body 221 of the filter 220 in order to seal between the outer circumferential surface of the filter 220 and the inner circumferential surface of the housing 210 . After inserting the second sealing member 227 such as an O-ring into the seating groove 226 , the filter 220 may be inserted into the housing 210 to be coupled thereto. At this time, the seating groove 226 is formed on the upper side of the locking jaw 228 formed in the body 221 , and is formed on the upper side where the step 211 of the housing 210 and the locking jaw 228 of the filter 220 are in close contact. The second sealing member 227 may be disposed, and the force acting on the second sealing member 227 by the pressure of the heat exchange medium acting from the lower side to the upper side of the housing 210 partitioned by the filter 220 . This can be very small, sealing performance can be improved, and durability of the second sealing member 227 can also be improved.

In addition, the filter 220 has a recessed seating groove 226 formed on the outer circumferential surface of the body 221 in the circumferential direction so that the second sealing member 227 is inserted into the seating groove 226, the seating groove ( 226 is formed on the lower side of the locking protrusion 228, the upper side of the step 211 may be formed with an inclined surface 212 inclined toward the inner lower side.

That is, opposite to the above, as shown in FIG. 7 , the seating groove 226 is formed on the lower side of the locking jaw 228 , and the upper side of the stepped 211 is formed as an inclined surface 212 inclined inwardly downward, the filter 220 . When a second sealing member 227, such as an O-ring, is inserted and coupled to the seating groove 226 of 212) can be easily inserted to the lower side, so that when the filter 220 is inserted into the housing 210 and assembled, damage to the second sealing member 270 can be prevented, thereby reducing the occurrence of airtightness.

And a seating groove 233 is formed concavely along the circumferential direction on the outer peripheral surface of the body 231 of the cap 230, and the first sealing member 234 is inserted into the seating groove 233, the first sealing member 234. Thus, a space between the cap 230 and the housing 210 may be sealed.

In addition, the filter 220 has a guide tube 223 extending from the refrigerant inlet 222 , so that the rising tube 240 is fitted and coupled to the guide tube 223 .

That is, a guide tube 223 extending downward is formed in the refrigerant inlet 222 formed on the lower side of the filter 220 , and the upper end of the rising tube 240 is inserted into the guide tube 223 to be coupled and fixed. In addition, the riser pipe 240 may be connected to the refrigerant inlet 222 .

And the condenser 1000 of the present invention, a pair of header tanks 100 are spaced apart from each other and formed side by side; an inlet pipe 110 and an outlet pipe 120 formed in the one side of the header tank 100 to allow a heat exchange medium to flow in or out; a plurality of baffles 130 provided inside the header tank 100 to control the flow of a heat exchange medium; a plurality of tubes 160 having both ends fixed to the pair of header tanks 100 to form a flow path of a heat exchange medium; a fin 170 interposed between the tubes 160; and the gas-liquid separator 200 provided on the other side of the header tank 100 to separate the gas-phase heat exchange medium and the liquid-phase heat exchange medium; The header tank 100 and the tube 170 are partitioned by the baffle 130 to form a condensation area A1 at the lower portion and a subcooling area A2 at the upper portion, so that the gas-liquid The refrigerant inlet hole 213 of the separator 200 may be connected to the condensing area A1 through the lower communication pipe 140 , and the refrigerant discharge hole 214 may be connected to the supercooling area A2 through the upper communication pipe 150 .

Here, as shown in FIGS. 2 and 3 , the header tank 100 is a space in which the heat exchange medium is introduced and discharged, and is a part for guiding the heat exchange medium to the tube 160 , and may be spaced apart from each other by a predetermined distance and formed side by side. In the header tank 100 of the inlet pipe 110 and the outlet pipe 120 may be formed. In addition, the tubes 170 are connected so that both ends are fixed to the pair of header tanks 100 to form a flow path of the heat exchange medium, and the fins 170 may be interposed between the tubes 160 . In addition, a baffle 130 that blocks the flow of the heat exchange medium in the height direction may be formed inside the header tank 100 to control the flow of the heat exchange medium, and the baffle 130 is provided at the outlet at the left header tank 100 . The lower side of the pipe 120 and the lower side of the inlet pipe 110 are respectively formed, and the lower side of the upper communication pipe 150 of the right header tank 100 and the upper side of the lower communication pipe 140 may be respectively formed. In this case, the pair of baffles 130 formed below the outlet pipe 120 of the left header tank 100 and the lower side of the upper communication pipe 150 of the right header tank 100 may be formed at the same height. Thus, the tubes 160 and the fins 170 configured on the lower side of the pair of baffles 130 become the condensation region A1, and the tubes 160 and the fins 170 configured on the upper side are the subcooling regions. Divided into (A2), the heat exchange medium introduced into the inlet pipe 110 passes through the condensing region A1 and is cooled, so that the gaseous refrigerant is converted into a liquid refrigerant, and the gas-liquid separator 200 along the lower communication pipe 140 The upper sub is introduced, flows upward along the riser pipe 240, flows into the supercooling region A2 through the upper communication pipe 150, passes through the supercooling region A2, is supercooled, and is discharged to the outlet pipe 120. A sub-cool type condenser may be configured. In addition, the gas-liquid separator 200 connected to the lower communicating pipe 140 and the upper communicating pipe 150 may be coupled to one side of the right header tank 100 .

Thus, in the flow of the heat exchange medium in the condenser 1000 of the present invention, the heat exchange medium introduced into the inlet pipe 110 passes through the condensation area A1 and is cooled, so that the gaseous refrigerant is converted into a liquid refrigerant, and the lower communication pipe ( 140) flows into the gas-liquid separator 400, moisture is removed from the drying material 250, the gaseous refrigerant is separated upward, and only the liquid refrigerant flows into the lower end of the riser tube 240 and flows upward. It flows into the refrigerant inlet 222 of the filter 220, passes through the filter medium 225, is discharged to the refrigerant outlet 224, flows along the upper communication pipe 150, is supercooled in the supercooling region A2, and the outlet pipe ( 120) can be released.

The present invention is not limited to the above-described embodiments, and the scope of application is varied, and anyone with ordinary knowledge in the field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims It goes without saying that various modifications are possible.

1000: condenser
100: header tank
110: inlet pipe 120: outlet pipe
130: baffle 140: lower communication pipe
150: upper communication pipe 160: tube
170: pin
200: gas-liquid separator
210: housing 211: stepped
212: slope 213: refrigerant inlet hole
214: refrigerant discharge hole
220: filter
221: body 222: refrigerant inlet
223: guide tube 224: refrigerant outlet
225: filter medium 226: seating groove
227: second sealing member
230: cap 231: body
232: close contact protrusion 233: seating groove
234: first sealing member 235: male thread
240: riser
250: drying material

Claims (9)

The housing 210 is formed as an open tube at the top and arranged in the height direction, the refrigerant inlet hole 213 is formed on the lower side, and the refrigerant outlet hole 214 is formed on the upper side;
It is inserted into the housing 210 and coupled to the housing 210 to be disposed below the refrigerant discharge hole 214 , and a space is formed in the body 221 to communicate with the space at the lower side of the refrigerant inlet. 222 is formed, the refrigerant outlet 224 is formed on the upper side, is provided in the space portion, is installed between the refrigerant inlet 222 and the refrigerant outlet 224, the refrigerant inlet 222 and the refrigerant outlet 224 ) one filter medium 225 formed to partition the installed filter 220;
a cap 230 coupled to the open upper end of the housing 210 and having a lower end in close contact with or coupled to the filter 220; and
a rising pipe 240 having an upper end coupled to and connected to the refrigerant inlet 222 of the filter 220 and having a lower end disposed below the inner side of the housing 210; is made, including
The cap 230 has a body 231 coupled to the housing so that the lower surface of the body 231 is located above the refrigerant discharge hole 214 of the housing 210 , and protrudes from the lower surface of the body 231 to the lower side. 232 is extended so that the lower end of the close contact protrusion 232 is coupled to the upper surface of the filter 220 so that the outer diameter of the close contact protrusion 232 is smaller than the outer diameter of the body 221 of the filter 220 become,
The close contact protrusion 232 is formed in the form of a single cylinder disposed on the same axis as the central axis of the cap 230 and presses the center of the upper surface of the filter 220,
The refrigerant outlet (224) is a gas-liquid separator, characterized in that formed around the contact projection (232).
According to claim 1,
The housing 210 has a stepped 211 protruding from the inner circumferential surface of the lower side of the refrigerant discharge hole 214 , and the filter 220 has a protruding hook 228 on the outer circumferential surface, so that the locking jaw 228 is formed. ) gas-liquid separator characterized in that it is coupled to be caught on the step (211).
delete According to claim 1,
The filter medium (225) of the filter (220) is formed in the form of a plate or membrane to partition the inner space of the body (221), and is coupled to the body (221).
According to claim 1,
The filter 220 is a gas-liquid separator, characterized in that the body 221 and the filter medium 225 are integrally formed by insert injection.
3. The method of claim 2,
The filter 220 has a recessed seating groove 226 formed on the outer circumferential surface of the body 221 in the circumferential direction, so that the second sealing member 227 is inserted into the seating groove 226, the seating groove 226 Gas-liquid separator, characterized in that formed on the upper side of the locking jaw (228).
3. The method of claim 2,
The filter 220 has a recessed seating groove 226 formed on the outer circumferential surface of the body 221 in the circumferential direction, so that the second sealing member 227 is inserted into the seating groove 226, the seating groove 226 The gas-liquid separator is formed on the lower side of the locking step 228, and the upper side of the step 211 is inclined toward the inner and lower side, and the inclined surface 212 is formed.
According to claim 1,
The filter 220 is a gas-liquid separator, characterized in that the guide tube (223) is formed extending from the refrigerant inlet (222), the riser tube (240) is fitted to the guide tube (223) is coupled.
In the condenser comprising the gas-liquid separator 200 of any one of claims 1 to 2, 4 to 8,
A pair of header tanks 100 are spaced apart from each other and formed side by side;
an inlet pipe 110 and an outlet pipe 120 formed in the one side of the header tank 100 to allow a heat exchange medium to flow in or out;
a plurality of baffles 130 provided inside the header tank 100 to control the flow of a heat exchange medium;
a plurality of tubes 160 having both ends fixed to the pair of header tanks 100 to form a flow path of a heat exchange medium;
a fin 170 interposed between the tubes 160; and
the gas-liquid separator 200 provided on the other side of the header tank 100 to separate the gas-phase heat exchange medium and the liquid-phase heat exchange medium; is made, including
The header tank 100 and the tube 170 are partitioned by the baffle 130 so that a condensation area A1 is formed at the lower portion and a subcooling area A2 is formed at the upper portion, so that the refrigerant of the gas-liquid separator 200 is formed. Condenser, characterized in that the inlet hole (213) is connected to the lower communication pipe (140) to the condensing area (A1), and the refrigerant discharge hole (214) is connected to the upper communication pipe (150) to the supercooling area (A2).

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