KR20210105822A - Heat exchanger having tank structure distributing heat-exchanger fluid for dispersing thermal stress - Google Patents

Abstract

The present invention relates to a heat exchanger having a flow distribution tank structure for releasing thermal stress. The present invention is to provide a heat exchanger having a flow distribution tank structure for dispersing thermal stress that has a flow distribution structure in the tank to effectively disperse the thermal stress generated by the temperature difference, in the integrated heat exchanger for cooling two types of heat exchange media having different temperature.

Description

Heat exchanger having tank structure distributing heat-exchanger fluid for dispersing thermal stress

The present invention relates to a heat exchanger, and more particularly, in an integrated heat exchanger for cooling two types of heat exchange media having different temperatures, each having a flow rate distribution structure in a tank to effectively disperse thermal stress generated due to a temperature difference It is about the heat exchanger.

In general, in the engine room of a vehicle, various heat exchangers such as radiators, intercoolers, evaporators, condensers, etc. for cooling each component in the vehicle, such as the engine, or adjusting the air temperature inside the vehicle, as well as parts for driving such as the engine, etc. are provided In such heat exchangers, a heat exchange medium generally circulates therein, and the heat exchange medium inside the heat exchanger and the air outside the heat exchanger exchange heat with each other, thereby cooling or dissipating heat.

In many cases, one type of heat exchange medium is circulated in the heat exchanger, but if necessary, heat exchangers through which two types of heat exchange medium are circulated may be integrally formed. For example, in the case of a radiator and an oil cooler of a vehicle, coolant for cooling the engine is circulated to the radiator, and oils such as engine oil and transmission oil are circulated to the oil cooler. Of course, there are cases where they are each formed as separate devices, but in many cases they are integrally formed, such as for the purpose of increasing engine room space utilization or a water-cooled oil cooler structure for cooling oil using cooling water is introduced.

1 shows an embodiment of a conventional integrated heat exchanger in which two types of heat exchange media are circulated. The integrated heat exchanger according to the embodiment of FIG. 1 has a structure substantially similar to that of a heat exchanger through which one type of heat exchange medium is circulated. That is, the heat exchanger 1000 includes a pair of header tanks 100 spaced apart from each other and formed side by side, and a plurality of tubes 200 having both ends fixed to the header tank 100 to form a flow path of the refrigerant. , additionally includes a plurality of fins 300 interposed between the tubes 200 . In addition, a baffle for partitioning and isolating the inner space of the header tank 100 is provided so that the two types of heat exchange media can be distributed without being mixed with each other, or the header tank 100 itself is divided into a divided form. is done 1 shows an embodiment in which the header tank 100 is divided. In addition, unlike the heat exchanger that distributes one type of heat exchange medium has one inlet/outlet, the heat exchanger that distributes two types of heat exchange medium has two inlet/outlet each.

On the other hand, such an integrated heat exchanger replaces, say, two heat exchangers with one heat exchanger. Therefore, compared to the case of two heat exchangers, since the area of the core of the heat exchanger (core, a region composed of tubes and fins, where heat exchange is mainly performed) is reduced, it is necessary to further improve heat exchange performance. According to this need, in the case of such an integrated heat exchanger, there is a case in which the tube is formed in a form in which a partition wall is formed in the middle so that the heat exchanger core is formed double. 1 is a cross-sectional view of a tube having a partition wall formed in the middle as described above. The shape of the tube in which the partition wall is formed in the middle may be manufactured using extrusion, or may be manufactured using a fold as shown in the lower part of FIG. 1 . As a folded tube, an example of a tube having a partition wall formed in the middle is well shown in Korean Patent Laid-Open No. 2013-0023450 (“heat exchanger”, 2013.03.08.).

That is, the heat exchanger core is separated into two in the vertical direction, so that two types of heat exchange media are circulated, and each of the upper and lower cores is also divided into two in the front and rear directions. they communicate with each other

In the integrated heat exchanger formed as described above, two types of heat exchange media having different types, such as coolant/oil, are circulated, or two types of heat exchange media having different temperature ranges, such as low-temperature coolant/high-temperature coolant, are distributed in various ways. is operated In any case, a significant temperature difference is formed between the upper and lower cores when the two types of heat exchange media are circulated. Meanwhile, a temperature difference also occurs between the front and rear cores, which will be described in detail as follows. Such a heat exchanger is configured such that the heat exchange medium in the heat exchanger exchanges heat with the outside air while external air is circulated in the front and rear directions. At this time, when the core is double formed in the front-rear direction due to the tube having the partition wall, the air that has already exchanged heat with the front core is heat-exchanged with the rear core. Accordingly, a temperature difference also occurs between the front and rear cores.

As such, when the temperature distribution is unbalanced, the degree of thermal deformation varies depending on the location, and accordingly, there is a problem in that the thermal stress is concentrated in a specific part of the heat exchanger. In the case of the integrated heat exchanger as described above, the concentration of thermal stress is greatest in the portion where the upper and lower cores and the front and rear cores are divided. Since the concentration of thermal stress due to such thermal deformation is a major cause of damage or breakage of the heat exchanger, a countermeasure design is required.

1. Korean Patent Publication No. 2013-0023450 (“Heat Exchanger”, 2013.03.08.)

Accordingly, the present invention has been devised to solve the problems of the prior art as described above, and an object of the present invention is to provide an integrated heat exchanger that cools two types of heat exchange media having different temperatures. An object of the present invention is to provide a heat exchanger having a flow distribution structure in the tank to effectively distribute thermal stress, and having a flow distribution tank structure for thermal stress distribution.

The heat exchanger 1000 having a flow distribution tank structure for thermal stress distribution of the present invention for achieving the above object is formed by combining the header 110 and the tank 120, and is spaced apart from each other by a certain distance and side by side In the heat exchanger 1000 including a pair of header tanks 100 formed to When the coming direction is the front, the blowing direction is the rear, the extension direction of one side of the header tank 100 is the first direction, and the other side is the second direction, the heat exchanger 1000 is inside the header tank 100 . The space is separated in the first and second directions so that heat exchange media having different average temperatures are circulated to each of the first and second direction heat exchange units, and the inner space of the tube 200 is separated back and forth to form a double heat exchange unit before and after The flow rate in the tank 120 so that the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube 200 is relatively smaller than the flow rate of the heat exchange medium flowing into the inner space on the front side of the tube 200. A distribution structure may be formed.

At this time, in the flow distribution structure, a part of the tank 120 protrudes inside the header tank 100 in the height direction of the header tank 100 , and the end of the protrusion is spaced apart from the inner space at the rear side of the tube 200 . The flow control rib 122 and the header tank 100 are extended in the height direction, and one end is fixed to the inner surface of the flow control rib 122 and the other end is spaced apart from the inner space of the tube 200 rear side. Including the baffle 121, it can be formed as a combination of the flow rate control rib 122 and the flow rate control baffle 121 that are formed to reduce the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube 200 have.

Also at this time, in the flow distribution structure, the number of the tubes 200 for which the flow rate is reduced by the flow rate control baffle 121 is the number of the tubes 200 for which the flow rate is reduced by the flow rate control rib 122 . It may be formed to be less or the same.

In addition, at this time, in the flow distribution structure, an isolation structure for separating and dividing the inner space of the header tank 100 in the first and second directions is formed at the boundary point of the first and two-way heat exchange units of the tank 120, and the The number of the tubes 200 for which the flow rate is reduced by the flow rate control baffle 121 is formed to be less than the number of the tubes 200 for which the flow rate is reduced by the flow rate control rib 122, the flow rate control baffle ( 121) may be formed at a position biased to the isolation structure.

Alternatively, in the flow distribution structure, a part of the tank 120 protrudes into the header tank 100 in the height direction of the header tank 100, and the end of the protrusion is spaced apart from the inner space at the rear of the tube 200, , it may be a flow rate control rib 122 formed to reduce the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube 200 .

Alternatively, the flow distribution structure extends in the height direction of the header tank 100 , and one end is fixed to the inner surface of the tank 120 and the other end is spaced apart from the inner space at the rear side of the tube 200 , and the tube 200 ) may be a flow rate control baffle 121 formed to reduce the flow rate of the heat exchange medium circulating into the rear inner space.

In addition, in the tank 120, an isolation structure is formed to isolate and partition the inner space of the header tank 100 in the first and second directions at the boundary of the first and second direction heat exchange units, and the isolation structure includes the tank ( 120) a part of the isolation rib that protrudes inside the header tank 100 in the height direction of the header tank 100, and the end of the protrusion is formed to contact the tube 200, or the height direction of the header tank 100 It may be an isolation baffle extending to the doedoe, one end being fixed to the inner surface of the tank 120 and the other end being formed so as to be in contact with the tube 200 .

In addition, when the flow rate distribution structure includes the flow rate control rib 122 and the isolation structure is the isolation rib, the flow rate control rib 122 and the isolation rib may be connected to each other.

In addition, the flow distribution structure may be formed on the side from which the heat exchange medium is discharged from the tube 200 .

In addition, the flow distribution structure may be applied to all positions of the tubes 200, or may be applied to positions of some of the tubes 200 in the vicinity of the first and two-way heat exchange unit boundary points.

At this time, the flow distribution structure is applied to a portion of the tube 200 in the vicinity of the boundary of the first and two-way heat exchange parts, and the vicinity of the boundary of the first and two-way heat exchangers is formed in the vicinity of the boundary of the heat exchanger 1000 ) may be formed in the range of 1 to 5 in the first and second directions around the dummy tube 210 formed at the boundary of the first and second direction heat exchange units.

In addition, the tube 200 may be formed with a partition wall separating the inner space of the tube 200 back and forth by bending the plate.

In addition, the heat exchanger 1000 may be a radiator that distributes high-temperature cooling water and low-temperature cooling water.

According to the present invention, in the integrated heat exchanger for cooling two types of heat exchange media having different temperatures, the flow rate distribution structure is formed in the tank, thereby effectively dispersing the thermal stress generated due to the temperature difference. More specifically, in the heat exchanger of the present invention, the core of the heat exchanger is divided into first and second directions for cooling two types of heat exchange media, and a tube having a partition wall formed in the middle, such as a folded tube, is used to improve heat exchange performance. It is divided into before and after. At this time, it is known that the concentration of thermal stress in the first and second directions and the front and rear division points, among them, the rear point is the most severe. At this time, in the present invention, a heat exchange medium having a greater flow rate is circulated to the front side of the tube and a heat exchange medium having a lower flow rate is circulated to the rear side of the tube to relieve the concentration of thermal stress, but such flow distribution is applied to the baffle formed in the tank or It is realized by using the tank depression.

By forming the flow distribution structure in this way, more heat exchange medium flowing through the tube front side exchanges heat with the outside air that has not yet been heat-exchanged, and less heat exchange medium flowing through the tube rear side exchanges heat with outside air that has been heat-exchanged once in the front core. By heat exchange, there is an effect that can greatly solve the problem of temperature imbalance. Of course, thereby, thermal stress is effectively dispersed, and ultimately, it is possible to obtain the effect of greatly reducing the problem of damage and breakage in the connection between the header and the tube.

1 is an embodiment of an integrated heat exchanger in which two types of conventional heat exchange media are distributed.
2 is an exploded perspective view of a conventional integrated heat exchanger in which two types of heat exchange media are distributed;
3 is an example of temperature distribution imbalance in the heat exchanger.
Figure 4 is a first embodiment of the flow distribution structure for thermal stress dispersion of the present invention.
5 is a second embodiment of a flow distribution structure for dissipating thermal stress of the present invention.
6A to 7 are a third embodiment of a flow distribution structure for dissipating thermal stress of the present invention.

Hereinafter, a heat exchanger having a flow rate distribution structure for dispersing thermal stress according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

The heat exchanger to be dealt with in the present invention is an integrated heat exchanger configured to separately circulate different types of heat exchange media having different temperatures. The first, second, and front and rear heat exchangers are double formed. To be more specific, as briefly described above with reference to FIG. 1 , the heat exchanger 1000 is formed in the form of a housing by combining the header 110 and the tank 120 , as long as they are formed side by side spaced apart from each other by a certain distance. A pair of header tanks 100 and a plurality of tubes 200 having both ends fixed to the header tank 100 to form a refrigerant passage, and a plurality of fins interposed between the tubes 200 ( 300) may be further included. At this time, in the heat exchanger 1000 , when one side of the header tank 100 in the extending direction is referred to as the first direction and the other side is referred to as the second direction, the inner space of the header tank 100 is separated in the first and second directions. It is partitioned so that heat exchange media having different average temperatures are circulated to each of the first and second direction heat exchange units. In the drawings, the first and second directions are illustrated as vertical directions, but of course, the present invention is not limited thereto. For example, the first and second directions may be left and right directions. In addition, in the heat exchanger 1000, when the blowing direction of the external air is referred to as the front and the blowing direction is referred to as the rear, the inner space of the tube 200 is separated back and forth to form a double heat exchange part back and forth. The tube 200 may be an extruded tube manufactured by extruding through a mold, or a folded tube in which a partition wall separating the inner space of the tube 200 back and forth is formed by bending the plate. Also, for example, the heat exchanger 1000 may be a radiator that distributes high-temperature coolant/low-temperature coolant.

2 is an exploded perspective view of a conventional integrated heat exchanger in which two types of heat exchange media are circulated. 2 is a view for showing in detail that the heat exchange unit is partitioned in the first and second directions (up and down direction when viewed in reference to FIG. 2 ). For convenience, a tube 200 or a fin 300 excluding the dummy tube 210 is omitted and shown. A dummy tube has the same external shape as a general tube and is formed so that it can be smoothly inserted into the tube insertion hole of the header. It is a tube in the shape of Since the tube 200 serves to circulate the heat exchange medium between the pair of header tanks 100 , the heat exchange medium does not flow between the pair of header tanks 100 at the point where the dummy tube 210 is formed. does not Therefore, in order to form the first and second direction heat exchange units, the inner space of the header tank 100 needs only to be separated in the first and second directions at the point where the dummy tube 210 is formed. As a result, the boundary point of the first and second direction heat exchange units may be defined as a point at which the dummy tube 210 is formed.

As such, in the heat exchanger 1000, the inner space of the header tank 100 is separated in first and second directions. ) An isolation structure that separates the inner space in the first and second directions may be formed. The isolation structure may be an isolation baffle having one end fixed to the inner surface of the tank 120 and the other end being formed to contact the dummy tube 210, or as shown in FIG. 2, a part of the tank 120 is It may be an isolation rib that protrudes inside the header tank 100 so that the end of the protrusion is in contact with the dummy tube 210 .

3 shows an example of temperature distribution imbalance in the heat exchanger in detail.

Exemplarily, as shown in the upper side of FIG. 3 , the upper heat exchange part of the heat exchanger 1000 forms a hot zone, and the lower heat exchange part of the heat exchanger 1000 forms a cold zone. can be formed As such, when a temperature difference occurs between the first and two-way heat exchange units, thermal stress is concentrated at the boundary point of the first and two-way heat exchange units due to a difference in the amount of thermal deformation in the first and two-way heat exchange units.

A top view and a temperature distribution graph of the heat exchanger 1000 are shown in the middle of FIG. 3 . The temperature distribution graph shows a phenomenon that the temperature gradually decreases while the heat exchange medium flows from the inlet to the outlet of the tube 200 and exchanges heat with external air. However, as can be seen here, the temperature of the rear side is generally higher than that of the front side of the tube 200 . That is, it can be seen that the heat exchange medium flowing into the inner space of the front side of the tube 200 is cooled better than the heat exchange medium flowing through the inner space of the rear side of the tube 200 . 3, a temperature distribution graph displayed in more detail at the inlet portion of the tube 200 is shown on the lower side of FIG. 3 , but here as well, the overall temperature of the rear side is higher than that of the front side, so that it can be confirmed that the cooling of the heat exchange medium is not sufficiently performed. can

The temperature distribution imbalance will be described in more detail as follows. The heat exchange medium flowing into the inner space of the front side of the tube 200 exchanges heat with air first. As described above, if the heat exchanger 1000 is a radiator, since the temperature of the air is lower than that of the heat exchange medium, the heat of the heat exchange medium is discarded to the air, thereby increasing the temperature of the air. The heat exchange medium circulated to the inner space of the rear side of the tube 200 exchanges heat with the air whose temperature has already risen slightly from the front side as described above. Accordingly, the heat of the heat exchange medium is not smoothly discharged into the air at the rear side compared to the front side, and thus the heat exchange medium is cooled less, so that the overall temperature of the rear side is higher than that of the front side of the tube 200 .

As such, when the temperature of the rear side of the tube 200 increases, of course, the amount of thermal deformation in the corresponding portion increases. On the lower side of FIG. 3, a state in which the rear side of the header 110 coupled to the rear side of the tube 200 causes more thermal deformation than the front side is indicated by a dotted line due to this temperature distribution imbalance. In general, the tube 200 is brazed after being inserted into the tube insertion hole of the header 110. As indicated by the dotted line, when the rear side of the header 110 is relatively stretched excessively due to thermal deformation, this joint is The thermal stress is excessively concentrated and eventually failure occurs.

That is, in summary, in the case of a heat exchanger having a double formation in both the first and second directions, the thermal stress is concentrated in the vicinity of the boundary point of the first and second direction heat exchange units in the first and second directions, and the rear in the front and rear directions. Thermal stress is concentrated at the side header-tube joint. Taken together, it can be seen that the thermal stress is the most concentrated at the rear header-tube junction near the boundary point of the first and second direction heat exchange units.

In the present invention, in order to solve this problem, the flow rate of the heat exchange medium flowing into the inner space of the rear side of the tube 200 is formed to be relatively smaller than the flow rate of the heat exchange medium flowing into the inner space of the front side of the tube 200 . As described above, a major cause of this unbalanced thermal deformation is that the heat exchange medium flowing into the inner space of the front side of the tube 200 first exchanges heat with air, so that the temperature of the air rises, and the air with this temperature rises in the tube. (200) This is because the heat cannot be sufficiently absorbed from the heat exchange medium circulating to the inner space of the rear side. At this time, if the flow rate of the heat exchange medium flowing into the inner space of the rear side of the tube 200 is reduced, the amount of heat that air must absorb from the heat exchange medium at the rear side is reduced. That is, if the flow rate of the heat exchange medium flowing into the inner space of the rear side of the tube 200 is reduced, even if the air does not absorb as much heat as the front side, heat sufficient to sufficiently lower the temperature of the rear side heat exchange medium can be absorbed. have. The present invention uses this principle, and in the present invention, a flow rate distribution structure is formed in the tank 120 so that the rear side has a lower flow rate of heat exchange medium than the front side.

Figure 4 shows a first embodiment of the flow distribution structure for thermal stress dissipation of the present invention. In the first embodiment, the flow distribution structure extends in the height direction of the header tank 100, and one end is fixed to the inner surface of the tank 120 and the other end is spaced apart from the inner space at the rear of the tube 200, , is formed as a flow rate control baffle 121 formed to reduce the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube 200 . 4 is a top view showing the other end of the flow control baffle 121 spaced apart from the rear end of the tube 200 by a predetermined distance, but of course, the present invention is not limited thereto. For example, the other end of the flow control baffle 121 may be formed to extend to the inner space of the tube 200. In this case, the outer diameter of the other end of the flow control baffle 121 is slightly smaller than the inner diameter of the tube 200. You may. That is, in this case, the other end of the flow control baffle 121 is fitted with a small gap in the inner space of the tube 200, and thus the flow rate can be reduced by reducing the flow path area itself.

5 shows a second embodiment of the flow distribution structure for thermal stress dissipation of the present invention. In the second embodiment, in the flow distribution structure, a part of the tank 120 protrudes inside the header tank 100 in the height direction of the header tank 100 , and the end of the protrusion is inside the rear side of the tube 200 . It is spaced apart from the space and is formed as a flow rate control rib 122 formed to reduce the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube 200 . The actual shape of the flow control rib 122 may be formed, for example, in a shape similar to that of the isolation rib shown in FIG. 2 . However, the isolation rib is formed to close both the front and rear sides of the tube 200 , while the flow control rib 122 is formed only on the rear side of the tube 200 . In addition, the isolation rib completely blocks the flow of the heat exchange medium, while the flow rate control rib 122 reduces the flow passage area but only reduces the flow rate by leaving a small gap through which the heat exchange medium can flow.

6A to 7 show a third embodiment of a flow distribution structure for dissipating thermal stress according to the present invention. To briefly summarize the third embodiment, it can be seen that the flow rate control baffle 121 of the first embodiment and the flow rate control rib 122 of the second embodiment described above are formed in a combined form. That is, in the third embodiment, in the flow distribution structure, a part of the tank 120 protrudes inside the header tank 100 in the height direction of the header tank 100 , and the end of the protrusion is at the rear side of the tube 200 . The flow control rib 122 is spaced apart from the inner space and extends in the height direction of the header tank 100, one end is fixed to the inner surface of the flow control rib 122, and the other end is from the inner space at the rear of the tube 200. The flow rate control rib 122 and the flow rate control baffle 121 are formed to reduce the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube 200, including the flow rate control baffle 121 that is spaced apart. formed as a compound.

The perspective view of FIG. 6A shows the header 110 as it is, but the tank 120 is cut at a portion where the flow distribution structure is formed, and the tube 200 also has the flow distribution structure formed therein. Shown only in scope. The perspective view of FIG. 6B shows a form in which the front half of the assembly of the header 110 and the tube 200 is cut, and corresponds to the cross-sectional view of FIG. 6C . 6C is a cross-sectional view of the same view as in FIGS. 4 and 5 , wherein the flow rate control rib 122 protrudes to the vicinity of the inlet on the rear side of the tube 200 , and the flow rate control rib 122 protrudes from the inner surface of the flow control rib 122 The flow rate control baffle 121 is further extended and protrudes to a position that almost meets the inlet on the rear side of the tube 200 is well shown. As such, since the flow distribution structure is formed, it is possible to very effectively reduce the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube 200 .

In the third embodiment, the flow distribution structure includes both the flow rate control rib 122 and the flow rate control baffle 121, and at this time, the tube ( 200) may be formed to be equal to or less than the number of the tubes 200, the flow rate of which is reduced by the flow control rib 122. On the other hand, in FIG. 6A and the like, the number of the tubes 200 for which the flow rate is reduced by the flow rate control baffle 121 is smaller than the number of the tubes 200 for which the flow rate is reduced by the flow rate control ribs 122. An example is shown. In this case, if the flow rate control baffle 121 is formed on the far side from the isolation structure, the empty space between the flow rate control baffle 121 and the isolation structure is a dead zone in which the heat exchange medium does not flow properly and accumulates substantially. (dead zone) will be formed, which causes a waste of space in the heat exchanger. Therefore, the flow control baffle 121 is preferably formed at a position biased to the isolation structure as shown.

Meanwhile, in the tank 120, an isolation structure is formed to isolate and partition the inner space of the header tank 100 in the first and second directions at the boundary of the first and second direction heat exchange units, and such an isolation structure is an isolation rib or isolation structure. It was explained that it could be a baffle. 6D is a view of the flow distribution structure from the outside of the tank 120 , and FIG. 6E is a view of the flow distribution structure as viewed from the inside of the tank 120 . Also, FIG. 6f is a perspective view of the flow distribution structure from the inside of the tank 120 . 6A to 6F, an example is shown in which the flow rate distribution structure includes the flow rate control rib 122, and the isolation structure is the isolation rib. In this case, if the flow control rib 122 and the isolation rib are formed independently of each other, the space between them becomes a dead zone as well as the deformation of the tank 120 in the space between them is excessively abrupt during the manufacturing process. There is a risk of defects such as breakage in the Accordingly, when the flow rate distribution structure includes the flow rate control rib 122 and the isolation structure is the isolation rib, the flow rate control rib 122 and the isolation rib are connected to each other as shown in FIGS. 6A to 6F . It is preferable to form

On the other hand, the flow distribution structure may be formed anywhere on the inlet side through which the heat exchange medium flows in the tube 200 or on the outlet side through which the heat exchange medium is discharged. However, when the flow distribution structure is formed on the inlet side of the tube 200 , the high-temperature heat exchange medium accommodated in the header tank 100 may not smoothly escape into the tube 200 . This may cause a decrease in heat exchange performance by unnecessarily increasing the pressure in the header tank 100 or by not allowing the heat exchange medium to flow smoothly into the tube 200 . Therefore, as indicated by 'outlet' in both FIGS. 4 and 5 , the flow distribution structure is preferably formed on the side from which the heat exchange medium is discharged from the tube 200 . By doing this, the fluidity of the heat exchange medium in the middle part of the tube 200 is sufficiently secured, and at the same time, the thermal stress is effectively dispersed at the crack point at the rear end of the tube 200 where the concentration of thermal stress occurs. can do it

In addition, the flow distribution structure may be applied to all the tube 200 positions. As long as the tube 200 is formed of two front and rear rows, the concentration of thermal stress to the header-tube rear side junction as described above may occur in all the tubes 200 . Therefore, the flow distribution structure may be applied to all the tubes 200 .

However, when the flow distribution structure is applied to all the tubes 200 in this way, the distribution of the heat exchange medium from the tube 200 to the header tank 100 on the discharge side may not be smooth, which is the heat exchanger ( 1000), which may lead to deterioration of heat exchange performance. At this time, as described above, another portion where thermal stress concentration occurs is the boundary point of the first and second direction heat exchange units. In consideration of this point, the flow rate distribution structure may be applied to a portion of the tube 200 in the vicinity of the boundary point of the first and two-way heat exchange units. At this time, the vicinity of the boundary point of the first and two-way heat exchange parts is 1 to 5 in the first and second directions centering on the dummy tube 210 formed at the boundary point of the first and two-way heat exchange part of the heat exchanger 200 . It can be formed in the range of dogs. 7 is an example in which the flow rate distribution structure of the third embodiment as shown in FIGS. 6A to 6F is formed with respect to the position of the tube 200 in the vicinity of the boundary point of the first and second direction heat exchange units in this way. is showing In this case, it is possible to properly prevent the deterioration of the heat exchange performance of the heat exchanger 1000 as a whole, and at the same time to effectively realize the thermal stress dispersion at the point where the thermal stress concentration occurs the most. Of course, the present invention is not limited thereto, and when a point where thermal stress concentration occurs is found during actual operation of the heat exchanger, the flow rate distribution structure may be locally applied to the corresponding area.

As described above, in the present invention, the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube is reduced, so the amount of heat that air that has already undergone heat exchange on the front side must absorb from the rear side (to sufficiently cool the heat exchange medium) reduce itself. Accordingly, even if the air does not absorb as much heat as the front side, the heat exchange medium at the rear side can be sufficiently and appropriately cooled. In other words, the temperature of the front heat exchange medium and the temperature of the rear heat exchange medium can be more uniformly matched. As such, by uniformizing the temperature distribution between the front and rear, the risk of damage due to concentration of thermal stress at the header-tube rear junction can be greatly reduced.

In addition, it is known that thermal stress concentration occurs at the boundary of the first and second direction heat exchange units. Therefore, if such a flow distribution structure is locally applied near the boundary of the first and second direction heat exchangers, the risk of damage due to concentration of thermal stress can be sufficiently reduced while maintaining the overall heat exchange performance of the heat exchanger appropriately.

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: heat exchanger
100: header tank
110: header 120: tank
121: flow control baffle 122: flow control rib
200: tube 210: dummy tube
300: pin

Claims (13)

A heat exchanger comprising a pair of header tanks formed by combining a header and a tank and spaced apart from each other and formed in parallel, and a plurality of tubes having both ends fixed to the header tank to form a flow path of a refrigerant,
When the blowing direction of the outside air is referred to as the front, the blowing direction is referred to as the rear, the extension direction of one side of the header tank is referred to as the first direction, and the other side is referred to as the second direction,
In the heat exchanger, the inner space of the header tank is separated in first and second directions, so that heat exchange media having different average temperatures are circulated to each of the first and second direction heat exchange units, and the inner space of the tube is separated back and forth so as to be doubled back and forth. It is made in the form of forming a heat exchange part of
so that the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube is formed to be relatively less than the flow rate of the heat exchange medium flowing into the inner space on the front side of the tube,
Heat exchanger, characterized in that the flow distribution structure is formed in the tank.
According to claim 1, The flow distribution structure,
A flow rate control rib in which a portion of the tank protrudes into the header tank in the height direction of the header tank and the end of the protrusion is spaced apart from the inner space at the rear side of the tube;
Including a flow control baffle extending in the height direction of the header tank, one end being fixed to the inner surface of the flow control rib and the other end being spaced apart from the inner space of the tube rear side,
and a combination of the flow rate control rib and the flow rate control baffle, which are formed to reduce the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube.
According to claim 2, The flow distribution structure,
The heat exchanger, characterized in that the number of the tubes whose flow rate is reduced by the flow rate control baffle is less than or equal to the number of the tubes whose flow rate is reduced by the flow rate control ribs.
According to claim 3, The flow distribution structure,
An isolation structure for separating and partitioning the inner space of the header tank in the first and second directions is formed at the boundary of the first and second direction heat exchange units of the tank,
The number of the tubes whose flow rate is reduced by the flow rate control baffle is formed to be less than the number of the tubes whose flow rate is reduced by the flow rate control ribs,
The heat exchanger, characterized in that the flow control baffle is formed at a position biased to the isolation structure.
According to claim 1, The flow distribution structure,
A part of the tank protrudes inside the header tank in the height direction of the header tank, and the end of the protrusion is disposed to be spaced apart from the inner space on the rear side of the tube,
and a flow rate control rib formed to reduce the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube.
According to claim 1, The flow distribution structure,
Doedoe extending in the height direction of the header tank, one end is fixed to the inner surface of the tank and the other end is spaced apart from the inner space on the rear side of the tube,
and a flow rate control baffle formed to reduce the flow rate of the heat exchange medium flowing into the inner space on the rear side of the tube.
According to any one of claims 2 to 6, wherein the tank,
An isolation structure for isolating and partitioning the inner space of the header tank in the first and second directions is formed at the boundary point of the first and two-way heat exchange units, the isolation structure comprising:
A part of the tank is an isolation rib that protrudes inside the header tank in the height direction of the header tank and is formed so that the end of the protrusion is in contact with the tube,
and an isolation baffle extending in the height direction of the header tank and having one end fixed to the inner surface of the tank and the other end being formed to contact the tube.
8. The method of claim 7,
When the flow distribution structure includes the flow control rib, and the isolation structure is the isolation rib,
The heat exchanger, characterized in that the flow control rib and the isolation rib are connected to each other.
According to claim 1, The flow distribution structure,
Heat exchanger, characterized in that formed on the side from which the heat exchange medium is discharged from the tube.
According to claim 1, The flow distribution structure,
applied to all of the tube locations, or
A heat exchanger, characterized in that it is applied to the position of the tube in the vicinity of the boundary point of the first and two-way heat exchangers.
11. The method of claim 10, wherein the flow distribution structure,
Doedoe applied to a portion of the tube position near the boundary point of the first and two-way heat exchange units,
The vicinity of the boundary of the first and two-way heat exchangers is formed in the range of 1 to 5 in the first and second directions around the dummy tube formed at the boundary of the first and two-way heat exchange of the heat exchanger. the heat exchanger.
According to claim 1, wherein the tube,
A heat exchanger, characterized in that the plate is bent to form a partition wall separating the inner space of the tube back and forth.
According to claim 1, wherein the heat exchanger,
A heat exchanger, characterized in that it is a radiator that distributes high-temperature cooling water and low-temperature cooling water.

Images