KR102228167B1 - Condenser - Google Patents

Abstract

The present invention relates to a condenser, and more particularly, in a water-cooled condenser, in which plates are stacked to form a condensation region in which the refrigerant condenses and a supercooled region in which the refrigerant is supercooled, wherein a gas-liquid separator is coupled between the condensation region and the subcooling region. By arranging the connecting plate and forming a refrigerant and coolant to flow between the condensing region and the subcooling region, the configuration and assembly are simplified.

Description

Condenser

The present invention relates to a condenser, and more particularly, in a water-cooled condenser, in which plates are stacked to form a condensation region in which the refrigerant condenses and a supercooled region in which the refrigerant is supercooled, wherein a gas-liquid separator is coupled between the condensation region and the subcooling region. By arranging the connecting plate and forming a refrigerant and coolant to flow between the condensing region and the subcooling region, the configuration and assembly are simplified.

In general, in the refrigeration cycle of an air conditioner for a vehicle, a liquid heat exchange medium absorbs the amount of heat as much as the heat of vaporization from the surroundings and the evaporator vaporizes the actual cooling action.

The gaseous heat exchange medium flowing from the evaporator to the compressor is compressed at high temperature and high pressure in the compressor, and the heat of liquefaction is released to the surroundings while the compressed gaseous heat exchange medium is liquefied while passing through the condenser, and the liquefied heat exchanger As the medium passes through the expansion valve again, it enters the low-temperature and low-pressure compressed vapor state, and then flows into the evaporator and vaporizes to form a cycle.

In other words, the condenser is formed by air cooling using air as a heat exchange medium for cooling the refrigerant, and water cooling using liquid as a heat exchange medium to cool the refrigerant. Can be.

1 is a view showing a conventional water-cooled condenser 10, a plate heat exchanger in which a plurality of plates 20 are stacked may be used.

In the conventional water-cooled condenser (10), a plurality of plates (20) are stacked to form a first flow unit (21) and a second flow unit (22) through which the first heat exchange medium and the second heat exchange medium respectively flow. 1 The first inlet pipe 31 and the first outlet pipe 32 through which the heat exchange medium flows in/out, the second inlet pipe 41 and the second outlet pipe 42 through which the second heat exchange medium flows in/out, the above A gas-liquid separator 50 separating the first heat exchange medium into a gaseous heat exchange medium and a liquid heat exchange medium, a first connection pipe 51 connecting the condensation region of the first flow unit 21 and the gas-liquid separator 50, and And a second connection pipe 52 connecting the gas-liquid separator and the subcooled region of the first flow unit 21.

In the water-cooled condenser (10), the first heat exchange medium introduced through the first inlet pipe (31) flows through the condensation region of the first flow unit (21), and the first connection pipe (51) It moves to the gas-liquid separator 50, flows through the subcooled region of the first flow part 21 again through the second connection pipe 52, and is discharged through the first outlet pipe 32.

At this time, the second heat exchange medium flows through the second inlet pipe 41 and flows in the second flow portion 22 formed by alternating with the first flow portion 21, and the first heat exchange medium Will cool down.

At this time, the water-cooled condenser 10 must have a first connection pipe 51 formed to inflow the refrigerant into the gas-liquid separator to separate gas-liquid, and a second connection pipe 52 for discharging the gas-liquid separated refrigerant. The configuration becomes complicated, and there is a problem in that the assembly efficiency of the condenser is deteriorated.

Republic of Korea Patent Publication No. 2012-0061534

The present invention has been conceived to solve the above-described problems, and an object of the present invention is to form a condensation region in which the refrigerant condenses and a supercooled region in which the refrigerant is supercooled by stacking plates in a water-cooled condenser. A condenser with simplified configuration and assembly is provided by arranging a connection plate to which a gas-liquid separator is coupled between the subcooling regions, and forming a refrigerant and coolant to flow between the condensing region and the subcooling region.

In the condenser according to the present invention, a plurality of first plates 110 and second plates 120 are alternately stacked in the longitudinal direction, so that the cooling water flow unit 130 through which the coolant flows and the refrigerant flow unit 140 through which the refrigerant flows are alternately stacked. A condensation region 200 in which the refrigerant is condensed and formed; In the longitudinal direction, a plurality of first plates 110 and second plates 120 are alternately stacked to form a coolant flow unit 130 through which coolant flows and a refrigerant flow unit 140 through which coolant flows. A supercooling area 300 in which supercooling is performed; A connection plate 400 disposed between the condensation region 200 and the subcooling region 300 in the longitudinal direction, and formed so that the condensation region 200 and the subcooling region 300 communicate with each other; And a gas-liquid separator 500 provided at one side in the width direction in communication with the connection plate 400. Particularly, a refrigerant inlet through which the refrigerant that has passed through the condensation region 200 flows into the refrigerant inlet part, which is provided on one side in the width direction in communication with the connection plate 400, and a refrigerant that discharges the gas-liquid-separated refrigerant to the subcooling region 300 Including a gas-liquid separator 500 including a discharge unit; wherein the first plate 110 and the second plate 120 are hollow so that the refrigerant flows through communication between the refrigerant flow units 140 formed alternately in the stacking direction. A refrigerant inflow and outflow hole 151 and a refrigerant flow hole 152; And a cooling water inflow hole 153 and a cooling water flow hole 154 communicated between the cooling water flow units 130 alternately formed in the stacking direction so that the cooling water flows, wherein the connection plate 400 is condensed. A connection plate body 410 formed to be coupled by making surface contact with the first plate 110 or the second plate 120 between the region 200 and the supercooling region 300, and the connection plate body 410 A cooling water connection passage 420 formed hollow so that the cooling water flow hole 154 of the condensation region 200 and the subcooling region 300 communicate with each other, and the condensation region ( A refrigerant inlet passage 431 communicating the refrigerant flow hole 152 of 200 and the refrigerant inlet portion, and a refrigerant outlet passage 432 communicating the refrigerant outlet portion and the refrigerant flow hole 152 of the subcooling region 300 It characterized in that it comprises a refrigerant flow path 430 including ).

In addition, the gas-liquid separator 500 includes a refrigerant inlet through which the refrigerant that has passed through the condensation region 200 flows in, and a refrigerant discharge part for discharging the gas-liquid-separated refrigerant to the subcooling region 300. .

In addition, the first plate 110 and the second plate 120 are communicated between the refrigerant flow units 140 formed alternately in the stacking direction, and a refrigerant outlet hole 151 and a refrigerant flow hole 151 that are hollow so that the refrigerant flows. 152); And a cooling water inflow hole 153 and a cooling water flow hole 154 communicated between the cooling water flow units 130 alternately formed in the stacking direction and hollow so that the cooling water flows.

In addition, the coolant flow hole 151 has a first protrusion 161 protruding toward the cooling water flow unit 130 around the periphery, and the coolant flow hole 152 is circumferentially toward the cooling water flow unit 130. A protruding second protrusion 162 is formed, and a third protrusion 163 protruding toward the refrigerant flow unit 140 is formed around the cooling water inflow hole 161, and the cooling water flow hole 154 is A fourth protrusion 164 protruding toward the refrigerant flow unit 140 is formed around the periphery.

In addition, the connection plate 400 includes a connection plate body 410 formed to be coupled to the first plate 110 or the second plate 120 between the condensation region 200 and the supercooling region 300. , A cooling water connection passage 420 formed by being hollow so that the cooling water flow hole 154 of the condensation region 200 and the supercooling region 300 communicates with the connection plate body 410, and the connection plate body 410 A refrigerant inlet passage 431 formed therein to communicate the refrigerant flow hole 152 of the condensation region 200 and the refrigerant inlet portion, and a refrigerant flow hole 152 of the refrigerant discharge portion and the subcooling region 300 It characterized in that it comprises a refrigerant flow passage 430 including a refrigerant discharge passage 432 communicating with.

In addition, the connection plate 400 is formed in an open shape so as to surround a part of the gas-liquid separator 500 in one side in the width direction, and further includes a gas-liquid separator coupling portion 440 that is located to which the gas-liquid separator 500 is coupled. It characterized in that it includes.

In addition, the connection plate 400 protrudes to the other side in the width direction, extends in the length direction, and includes an auxiliary fixing part 450 formed to be coupled to the side surface of the first plate 110 or the second plate 120. It characterized in that it further includes.

In the condenser according to the present invention, plates are stacked to form a condensation area where the refrigerant condenses and a subcooling area in which the refrigerant is supercooled, and a connection plate to which a gas-liquid separator is coupled is disposed between the condensation area and the supercooling area, and By forming the refrigerant and cooling water to flow therebetween, there is an advantage that the configuration and assembly are simplified.

In addition, the condenser according to the present invention has an advantage that can be replaced with an end plate connection plate of the first plate and the second plate stacked to form a condensing region and a supercooled region.

In addition, since the condenser according to the present invention can eliminate the pipe through which the refrigerant flows into and out of the gas-liquid separator, the configuration is simplified, and damage to the pipe due to external impact can be prevented, thereby preventing leakage of the refrigerant. There is an advantage.

1 is a view showing a conventional condenser.
2 is a perspective view showing a condenser according to an embodiment of the present invention.
3 is an exploded perspective view of a condenser according to an embodiment of the present invention.
4 is a view showing that the first plate is stacked in the condenser according to an embodiment of the present invention.
5 is a view showing that the second plate is stacked in the condenser according to an embodiment of the present invention.
6 is a view showing a connection plate and a gas-liquid separator of the condenser according to an embodiment of the present invention.

Hereinafter, a condenser according to an embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a condenser according to an embodiment of the present invention, Figure 2 is a view showing an exploded perspective view of the condenser according to an embodiment of the present invention, and Figure 3 is a view showing a condenser according to an embodiment of the present invention. It is a view showing the condenser in a cross-sectional view.

As shown in FIGS. 1 to 3, the condenser 1000 according to an embodiment of the present invention includes a condensation area 200 in which the refrigerant is condensed, a supercooling area 300 in which the refrigerant is supercooled, and a condensation area ( It comprises a connection plate 400 connected to communicate between the 200 and the subcooling region 300 and a gas-liquid separator 500 positioned on the connection plate.

In the condensation area 200, a plurality of first plates 110 and second plates 120 are alternately stacked in the longitudinal direction, through which cooling water flows in the space between the first plate 110 and the second plate 120 The cooling water flow unit 130 and the refrigerant flow unit 140 through which the refrigerant flows may be alternately formed, and the refrigerant is preferentially introduced to condense the refrigerant.

In the supercooling region 300, a plurality of first plates 110 and second plates 120 are alternately stacked in the longitudinal direction, through which cooling water flows in the space between the first plate 110 and the second plate 120 The cooling water flow unit through which the cooling water is flowed and the refrigerant flow unit 140 through which the refrigerant flows may be formed to be alternately formed, and the cooling water is preferentially introduced to perform supercooling of the refrigerant.

The connection plate 400 is disposed between the condensation region 200 and the supercooling region 300 in the longitudinal direction, and is formed so as to communicate the condensation region 200 and the supercooling region 300 with each other. The cooling water and the refrigerant in the subcooling region 300 may communicate with each other to flow.

The gas-liquid separator 500 communicates with the connection plate 400 and is provided on one side in the width direction, and a refrigerant inlet through which the condensed refrigerant flows through the condensation region 200 and the gas-liquid separated refrigerant is supercooled region 300. It includes a refrigerant discharge unit to be discharged.

That is, in the condenser 1000 according to an embodiment of the present invention, the refrigerant is preferentially introduced into the condensing region 200 to exchange heat with the cooling water, thereby condensing the refrigerant, and the condensed refrigerant is gas-liquid in the gas-liquid separator 500. After being separated, it flows to the subcooling region 300 and heat exchanges with the cooling water preferentially flowing into the subcooling region 300, thereby subcooling the refrigerant.

As opposed to the refrigerant, the coolant is formed to preferentially flow into the supercooling region 300 to exchange heat with the refrigerant, pass through the connection plate 400 to flow through the condensation region, and then discharge to the outside.

This is because the coolant is first supplied to the subcooling region 300 and flows, thereby improving the differential cooling of the refrigerant, which has the advantage of improving the efficiency of the air conditioning system of the vehicle.

In addition, the connection plate 300 is disposed between the condensation region 200 and the supercooling region 300 formed by stacking the first plate 110 and the second plate 120 to form the first plate 110 or the second plate. By being combined with the plate 120, there is an advantage in that the weight is reduced since there is no need to separately provide an end plate in which the first plate 110 and the second plate 120 are stacked.

The condenser 1000 according to an embodiment of the present invention described above will be described in more detail.

FIG. 4 is a view showing that a first plate is stacked in a condenser according to an embodiment of the present invention, and FIG. 5 is a view showing a second plate is stacked in a condenser according to an embodiment of the present invention.

As shown in Figs. 4 to 5, the first plate 110 and the second plate 120 are communicated between the refrigerant flow units 140 formed alternately in the stacking direction, and are hollow to allow the refrigerant to flow. (151) and refrigerant flow holes 152 are formed, and a cooling water inflow hole 153 and a cooling water flow hole 154 communicated with the cooling water flow units 130 formed alternately in the stacking direction to flow It is formed including.

At this time, the refrigerant inflow hole 151, the refrigerant flow hole 152, the cooling water inflow hole 153, and the cooling water flow hole 154 are adjacent to each corner in the first plate 110 and the second plate 120. It is preferably formed.

The refrigerant outflow hole 151 is formed to be hollow so that the refrigerant flows through communication between the refrigerant flow units 140 alternately formed in the stacking direction, and a first protrusion 161 protruding toward the cooling water flow unit 130 around the circumference thereof Is formed.

The refrigerant flow hole 152 is formed to be hollow so that the refrigerant flows through communication between the refrigerant flow units 140 alternately formed in the stacking direction, and a second protrusion 162 protruding toward the cooling water flow unit 130 around the circumference thereof Is formed.

The cooling water inflow hole 153 is formed by protruding between the cooling water flow units 130 alternately formed in the stacking direction to be hollow so that the cooling water flows, and a third projection 163 protruding toward the refrigerant flow unit 140 around the periphery Is formed.

The cooling water flow hole 154 is formed to be hollow so that cooling water flows between the cooling water flow units 130 formed alternately in the stacking direction, and a fourth protrusion 164 protruding toward the coolant flow unit 140 is formed around the circumference thereof. do.

In this case, the condenser 1000 according to an embodiment of the present invention may have a refrigerant inlet through which refrigerant flows in and a refrigerant outlet through which refrigerant is discharged into the refrigerant inlet hole 151 located on the outermost surface in the longitudinal direction.

In addition, a cooling water inlet through which cooling water is introduced and a cooling water outlet through which cooling water is discharged may be formed in the cooling water inflow hole 153 located on the outermost surface in the longitudinal direction.

Of course, the condenser 1000 according to an embodiment of the present invention preferably has a refrigerant inlet and a refrigerant outlet formed so that the refrigerant is preferentially introduced into the condensing region 200 and discharged through the supercooling region 300. In addition, it is preferable to form a cooling water inlet and a cooling water outlet so that the cooling water preferentially flows into the subcooling region 300 and is discharged after passing through the condensation region 200.

2 or 6, the connection plate 400 may include a connection plate body 410, a cooling water connection passage 420, and a refrigerant flow passage 420 largely.

The connection plate body 410 is disposed between the condensation region 200 and the supercooling region 300, and the first plate 110 or the second plate 120 stacked in the condensation region 200 and the supercooling region 300 It is formed to be combined with, and is combined with the first plate 110 and the second plate 120 to distinguish between the condensation area 200 and the supercooling area 300. It is possible.

The cooling water connection passage 420 is formed in the connection plate body 410 and is formed in a hollow shape so that the cooling water flow holes 154 of the condensation region 200 and the subcooling region 300 communicate with each other.

The cooling water connection passage 420 must be formed so as to be coupled to the cooling water flow hole 154, and is formed to be hollow, so that the cooling water in the condensation region 200 and the supercooling region 300 can flow.

At this time, in the condenser 1000 according to an embodiment of the present invention, since the cooling water is preferentially supplied to the subcooling region 300, the cooling water flowing into the subcooling region 300 is the cooling water flow hole 420 of the connection plate 400 After flowing through the condensation zone, it may be formed to be dischargeable.

The refrigerant flow path 430 is formed so that the refrigerant flow hole 152 of the condensation region 200 and the refrigerant flow hole 154 of the gas-liquid separator 500 and the supercooling region 300 communicate with each other, and largely, a refrigerant flow path ( It is formed to include 431 and the refrigerant discharge passage (432).

The refrigerant inlet passage 431 is formed inside the connection plate body 410 and is formed to communicate the refrigerant flow hole 154 of the condensation region 200 with the refrigerant inlet of the gas-liquid separator 500, and the refrigerant inlet passage ( 431 is communicated with the refrigerant flow hole 154 of the condensation region 200 in the longitudinal direction, but the gas-liquid separator 500 is provided on one side of the connection plate 400 in the width direction, so it is bent within the connection plate body 410 As a result, it may communicate with the refrigerant inlet of the gas-liquid separator 500.

The refrigerant discharge passage 432 is formed inside the connection plate body 410 and is formed to communicate the refrigerant discharge portion of the gas-liquid separator 500 and the refrigerant flow hole 154 of the supercooling region 300, and the refrigerant discharge passage 432 denotes a connection plate body 410 so as to communicate with the refrigerant discharge portion of the gas-liquid separator 500 formed on one side of the connection plate 400 in the width direction and the refrigerant flow hole 154 of the supercooling region 300 formed in the longitudinal direction. ) Can be formed to be bent in communication.

As described above, the condenser 1000 according to an embodiment of the present invention includes a condensation region 200 through which refrigerant is preferentially introduced and flows and a supercooled region 300 through which cooling water is preferentially introduced and flowed. Includes a connection plate 400 separating the region 200 and the supercooling region 300 from each other, and the connection plate 400 includes a first plate 110 or a second plate of the condensation region 200 and the supercooling region 300. A connection plate body 410 coupled to the plate 120, a cooling water connection passage 420 that is hollow inside the connection plate body 410 to allow cooling water to flow through the supercooling region 400 and the condensation region 200, and The refrigerant condensed in the condensation zone 200 flows to the gas-liquid separator 500 to separate the gas-liquid from the gas-liquid separator 500, and then flows the refrigerant to the refrigerant flow hole 154 of the supercooling zone 300 ( 430).

Through this, since the first plate 110 and the second plate 120 stacked in the condensation region 200 and the supercooling region 300 by the connection plate body 410 does not need to have an end plate separately, the weight This has the advantage of decreasing.

In addition, since the cooling water and the refrigerant can be communicated with each other through the connection plate 400 of a simple configuration, or can be supplied to the gas-liquid separator 500, the pipe pipe through which the refrigerant flows to the gas-liquid separator 500 is omitted, and connected. Since it can be replaced with the plate 400, there is an advantage that there is little risk of damage or leakage due to an external impact, and in particular, there is an advantage that the overall configuration and shape of the condenser 1000 are simplified.

In addition, the connection plate 400 further includes a gas-liquid separator coupling portion 440 formed in an open shape so as to surround a part of the gas-liquid separator 500 in one side in the width direction and positioned to be coupled to the gas-liquid separator 500.

As shown in the drawing, the gas-liquid separator coupling part 440 may be formed in an open shape by being curved corresponding to the outer circumferential surface of the gas-liquid separator 500 formed in a mostly cylindrical shape, through which the gas-liquid separator 500 It can be easily fixed to one side of the connection plate 400 in the width direction.

That is, in the condenser 1000 according to an embodiment of the present invention, since the gas-liquid separator 500 can be positioned and fixed at one side in the width direction through the connection plate 400, it is easy to arrange and fix the gas-liquid separator 500. There is one advantage, and this has the advantage of saving space in the longitudinal direction in a vehicle in which the condenser 1000 is provided.

In addition, since the gas-liquid separator coupling portion 440 of the connection plate 400 can be combined with the gas-liquid separator 500 by placing the gas-liquid separator coupling portion 440 at a position selected from both sides in the width direction, it is conveniently placed in various vehicles equipped with the condenser 1000 As it can be made, there is an advantage that it is easy to apply to various vehicles.

In addition, the connection plate 400 protrudes to the other side in the width direction, extends in the length direction, and is coupled to the side surfaces of the first plate 110 or the second plate 120 of the condensation area 200 and the supercooling area 300 It may further include an auxiliary fixing part 450 formed to be possible.

The auxiliary fixing part 450 is formed to be coupled to the side surfaces of the first plate 110 or the second plate 120 stacked in the condensation region 200 and the supercooling region 300, thereby supercooling the condensation region 200 Since the connection plate 400 can be firmly coupled between the regions 300, leakage of refrigerant or cooling water can be prevented.

Of course, the shape of the auxiliary fixing part 450 is not limited as long as it is a shape that can be easily combined with the first plate 110 or the second plate 120 of the condensation region 200 and the supercooling region 300, It goes without saying that an embodiment is possible.

The present invention is not limited to the above-described embodiments, and the scope of application is various, as well as various types of persons having ordinary knowledge in the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Of course, it is possible to perform modifications.

1000: condenser
110: first plate 120: second plate
130: cooling water flow unit 140: refrigerant flow unit
151: refrigerant flow hole 152: refrigerant flow hole
153: cooling water inflow hole 154: cooling water flow hole
161: first protrusion 162: second protrusion
163: third protrusion 164: fourth protrusion
200: condensation area
300: subcooling area
400: connection plate
410: connecting plate body
420: cooling water connection passage
430: refrigerant flow passage
431: refrigerant inlet passage 432: refrigerant discharge passage
440: gas-liquid separator coupling unit 450: auxiliary fixing unit
500: gas-liquid separator

Claims (7)

In the longitudinal direction, a plurality of first plates 110 and second plates 120 are alternately stacked to form a cooling water flow unit 130 through which coolant flows and a refrigerant flow unit 140 through which cooling water flows. A condensation zone 200 in which condensation takes place;
In the longitudinal direction, a plurality of first plates 110 and second plates 120 are alternately stacked to form a cooling water flow unit 130 through which coolant flows and a refrigerant flow unit 140 through which cooling water flows. A supercooling area 300 in which supercooling is performed;
A connection plate 400 disposed between the condensation region 200 and the subcooling region 300 in the longitudinal direction, and formed so that the condensation region 200 and the subcooling region 300 communicate with each other; And
A refrigerant inlet part communicated with the connection plate 400 and provided on one side in the width direction, through which the refrigerant passed through the condensation region 200 flows in, and a refrigerant discharge for discharging the gas-liquid separated refrigerant to the subcooling region 300 Including; gas-liquid separator 500 including a part,
The first plate 110 and the second plate 120 are
A refrigerant outflow hole 151 and a refrigerant flow hole 152 communicated between the refrigerant flow units 140 alternately formed in the stacking direction to flow the refrigerant; And
Including; a cooling water inlet hole 153 and a cooling water flow hole 154 communicated between the cooling water flow units 130 alternately formed in the stacking direction to flow the cooling water,
The connection plate 400 is
A connection plate body 410 formed in surface contact with the first plate 110 or the second plate 120 between the condensation region 200 and the supercooling region 300 so as to be coupled,
A cooling water connection passage 420 formed by being hollow so that the cooling water flow hole 154 of the condensation region 200 and the subcooling region 300 communicate with the connection plate body 410,
A refrigerant inlet passage 431 formed in the connection plate body 410 to communicate the refrigerant flow hole 152 of the condensation region 200 and the refrigerant inlet portion, and the refrigerant discharge portion and the subcooling region 300 A vehicle condenser comprising a refrigerant flow passage 430 including a refrigerant discharge passage 432 communicating with the refrigerant flow hole 152 of the.
delete delete The method of claim 1,
A first protruding part 161 protruding toward the cooling water flow part 130 is formed around the refrigerant inflow hole 151,
The refrigerant flow hole 152 has a second protrusion 162 protruding toward the cooling water flow unit 130 around the periphery,
The cooling water inflow hole 153 has a third protrusion 163 protruding toward the refrigerant flow part 140 around the periphery,
The cooling water flow hole (154) is a vehicle condenser, characterized in that a fourth protrusion (164) protruding toward the refrigerant flow portion (140) is formed around the periphery.
delete The method of claim 1,
The connection plate 400 is
A vehicle condenser, characterized in that it further comprises a gas-liquid separator coupling part 440 formed in an open shape to surround a part of the gas-liquid separator 500 in one side in the width direction, and positioned to be coupled to the gas-liquid separator 500.
The method of claim 1,
The connection plate 400 is
For a vehicle, characterized in that it further comprises an auxiliary fixing part 450 which protrudes to the other side in the width direction, extends in the length direction, and is formed to be coupled to the side surface of the first plate 110 or the second plate 120 Condenser.

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