KR100921625B1 - Multilayered Heat Exchanger - Google Patents

Abstract

The present invention relates to a laminated heat exchanger, and in particular, by expanding the inlet portion of the working fluid flow path flowing into the tube from the tank to reduce the resistance, thereby minimizing the pressure loss at the inlet side and improving the flow distribution of the working fluid, thereby increasing the heat exchange performance. A stacked heat exchanger is provided.

To this end, the present invention, the hole cup (Hole Cup, 11a, 11b) having a slot (Slot, 11d) is formed in the upper and lower ends, respectively, and the plurality of beads (11c) is embossed two sheets of plate at the center A plurality of tubes 12 interconnected by brazing are formed to form a plurality of tubes 12 through which working fluid flows, and upper and lower tanks 15 and 16, and the stacked tubes 12 In a laminated heat exchanger in which a corrugated heat dissipation fin 13 is interposed therebetween, and an outermost portion of the tube 12 is coupled to an end plate 19, an inlet portion of the flow passage 14 is directed toward the tank side. It is characterized in that the inclined structure or its inlet portion is expanded into a rectangular stepped structure so as to be a normal light strait, and the expansion size is gradually changed in the direction in which the working fluid flows in and flows.

Heat exchanger, flow path, inlet, expansion, pressure loss, flow distribution, step, slope

Description

Multilayered Heat Exchanger

1 is a perspective view showing a conventional stacked heat exchanger.

2 is a cross-sectional view taken along the line A-A in FIG.

FIG. 3 is a front view of the first and second plates constituting the tube in FIG. 1; FIG.

4 is a partially enlarged cross sectional view of FIG. 1;

Fig. 5 is a partially enlarged cross-sectional view of a tank showing a state in which a passage section of a tube is expanded in an inclined structure according to a first embodiment of the present invention;

FIG. 6 is a sectional view taken along the line B-B in FIG. 5; FIG.

7 is a cross-sectional view showing a state in which the inlet flow path cross section of the tube is expanded in a stepped structure according to the second embodiment of the present invention.

Fig. 8 is a partial sectional view showing an example in which the expansion pipe size of the flow path inlet portion of the tube is gradually increased in the flow direction of the working fluid according to the third embodiment of the present invention.

 Explanation of symbols on the main parts of the drawings

10 ... Stacked Heat Exchanger 11 ... Plate

12 ... Tube 13 ... Heat sink fin

14 ... Euro 15 ... Upper tank

16 ... lower tank 19 ... end plate

The present invention relates to a laminated heat exchanger, and in particular, when the working fluid is introduced into the flow path inlet of the tube through the working fluid inlet pipe, to minimize the pressure loss of the working fluid at the flow path inlet side to improve the flow distribution of the working fluid The present invention relates to a laminated heat exchanger in which a flow path inlet portion is expanded.

In general, a laminated heat exchanger is formed by alternately stacking tubes formed by joining a pair of plates and heat dissipation fins. Can be. The tank is connected with a working fluid inlet tube and a working fluid outlet tube for inflow and outflow of the working fluid toward the front side of the heat exchanger, and this type of heat exchanger is widely used in various air conditioners, particularly automotive air conditioners. have.

As an example, a conventional stacked heat exchanger is shown in Figs.

First, referring to Figures 1 and 3, the stacked heat exchanger 10 is formed with a hole cup (Hole Cup, 11a, 11b) having slots (11d) in the upper and lower ends, respectively, and a plurality of beads in the center portion (11c) a plurality of tubes (12) in which two plates (11c) embossed are joined to each other by brazing bonding are laminated, and a flow path (14) through which a working fluid flows and its upper and lower tanks (15, 16) and a structure in which the outermost portion of the tube 12 is joined by an end plate 19 through a corrugated heat dissipation fin 13 between the stacked tubes 12. consist of. In addition, the upper tank 15 is connected to the working fluid inlet pipe 17 for introducing the working fluid into the tank, the lower tank 16 is connected to the working fluid outlet pipe 18 for discharging the working fluid.

In the conventional stacked heat exchanger 10 having such a structure, when a working fluid, such as a refrigerant or cooling water, flows into the upper tank 15 of the working fluid inlet tube 12 through the working fluid inlet tube 17, it operates. The fluid flows through the slot 11d into the tank of the adjacent tube 12 and at the same time descends between the plurality of beads 11c formed in the tube 12. In this process, the working fluid exchanges heat with external air, and is discharged through the working fluid outlet pipe 18 via the slot 11d on the lower tank 16 side.

However, the conventional multilayer heat exchanger 10 described above has a tube material having a thickness of approximately 0.4 mm or less, and also, as shown in FIGS. 2 and 4, the inlet of the flow path 14 of the tube 12 into which the working fluid flows. Since the area (inlet width, d1) is also small, during the initial flow of the working fluid into the flow passage 14 through the inlet pipe 17, the flow resistance of the working fluid is increased, and the inflow flow rate is reduced, thereby allowing the flow between the tubes. As well as the temperature deviation occurs, there was a problem that the pressure loss of the tube inlet is increased.

In other words, when the inlet portion of the flow passage 14 into which the working fluid flows in as in the prior art becomes small, the passage flow rate of the working fluid becomes small, thereby increasing the flow resistance of the working fluid, resulting in uneven flow distribution of the working fluid. By doing so, there was a problem that the heat exchange performance is lowered.

Moreover, since the inlet portions of the flow passages 14 of the several tubes 12 have the same cross-sectional area in the working fluid flow direction, only the flow fluid 14 on the working fluid inlet pipe 17 side is biased and flows therefrom. As the flow velocity of the working fluid gradually decreases over a long distance, the working fluid does not flow uniformly inside the tube, resulting in a problem that the heat exchange performance of each tube varies.

Therefore, in order to solve the above-mentioned problems, the general object of the present invention is to equalize the flow distribution of the working fluid by minimizing the pressure loss and the temperature deviation by reducing the fluid resistance of the flow path inlet of the tube into which the working fluid flows. It is to make it possible to increase the heat exchange performance thereby.

In addition, another object of the present invention is to flow the working fluid introduced through the working fluid inlet pipe at a uniform flow rate in the working fluid flow direction to maintain the same amount of working fluid passing through each tube to improve the heat exchange performance There is.

In order to achieve the above object, in the present invention, a hole cup having a slot is formed in each of the upper and lower ends, and a plurality of tubes in which the plurality of beads are embossed and laminated to each other are laminated to a plurality of tubes by brazing. An inlet of the working fluid flow path, which forms a flow path through which working fluid flows, and an upper and a lower tank, and a corrugated heat dissipation fin between the stacked tubes, and combines the outermost part of the tube with an end plate. The site is characterized in that it is expanded in the upper tank side or lower tank side direction.

In addition, the present invention is the laminated heat exchanger, characterized in that the expansion pipe of the inlet portion of the working fluid flow path is inclined so as to be the upper and lower narrow side toward the upper tank or the lower tank side.

In addition, the present invention is the laminated heat exchanger, characterized in that the expansion of the inlet portion of the working fluid flow path is stepped in a square shape toward the upper tank or the lower tank side.

In addition, the present invention is the laminated heat exchanger, the working fluid is introduced into the upper tank side, the expansion size of the inlet portion of the working fluid flow path, characterized in that to gradually increase in the working fluid flow direction.

In addition, the present invention is the laminated heat exchanger, the working fluid is introduced into the lower tank side, the expansion size of the inlet portion of the working fluid flow path, characterized in that to gradually decrease in the working fluid flow direction.

Hereinafter, embodiments of the present invention will be described in detail by the accompanying drawings.

As shown in FIG. 1, the heat exchanger according to the present invention has a plurality of tubes 12 each having two plates 11 brazed and formed with a working fluid flow path 14. A pair of tanks 15 and 16 are formed at the lower end, respectively, and the working fluid inlet pipe 17 and the working fluid outlet pipe 18 for operating fluid inflow and outflow are connected to the pair of tanks 15 and 16. Since the case of a conventional laminated heat exchanger has been described as an example, the same reference numerals are given to the same components as those in the conventional construction, and detailed description thereof will be omitted.

In addition, the present invention, although not shown here, the upper and lower tanks for circulating the working fluid, the working fluid inlet pipe and working fluid outlet pipe connected to the upper and lower tanks for the inflow and outflow of the working fluid, An upper and lower header coupled to the upper and lower tanks and having a plurality of through holes formed at a bottom thereof, and a plurality of tubes having both ends inserted into and fixed to a plurality of through holes of the upper and lower headers to form a flow path for a working fluid therein; The same can be applied to a conventional multilayer heat exchanger composed of heat dissipation fins laminated between these tubes.

5 is a partially enlarged cross-sectional view showing a state in which an inlet portion into which the working fluid flows from the upper tank into the working fluid flow passage 14 is expanded according to the first embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along the line BB in FIG. It is shown.

As shown in FIG. 6, the present invention is expanded in an inclined structure such that the inlet portion of the working fluid flow passage 14 becomes the upper and lower narrowings in the upper tank 15 side. As shown in Fig. 5, the center has a shape in which its center is convexly curved to the outside. In particular, referring to Figure 6, the working fluid flow path 14 according to the present invention is a portion where the working fluid is initially introduced into the tube 12 through the upper tank 15, that is, the inlet width (d2) is the inlet width of Figure 1 It has a wider structure than (d1).

According to this configuration, when the working fluid flows into the working fluid flow path 14 of the tube 12 through the working fluid inlet pipe 17, the flow resistance of the working fluid flow path 14 is reduced due to the wider inlet portion. The flow rate pressure loss on the inlet side of the working fluid flow passage 14 is minimized, thereby uniformly distributing the flow rate of the working fluid flowing into each tube 12.

FIG. 7 is a longitudinal sectional view according to the second embodiment of the present invention, except that the inlet portion of the working fluid passage 14 has a stepped structure having a rectangular shape toward the upper tank 15 side. It has the same function as the flow path of the structure shown in FIG. 5 and FIG.

Expansion of the inlet portion of the working fluid flow path according to the first and second embodiments is performed by inserting a predetermined expansion tool into the inlet of the working fluid flow path, and the expansion operation is performed by the expansion tool of the working fluid flow path. This should be done so that the entrance and exit is freely possible.

8 is a third embodiment of the present invention, in which the inlet portion of the working fluid flow path is enlarged in the same manner as in the first or second embodiment, in which the expansion size is gradually increased in the working fluid flow direction. Partial cross-sectional view of the is shown.

In general, when the working fluid is introduced into the upper tank 15 through the working fluid inlet pipe 17, it is concentrated in the tank 15 close to the working fluid inlet pipe 17 side. Therefore, the working fluid concentrated there is lowered vertically by gravity, and the remaining part flows to the upper tank 15 side, and the amount of fluid gradually decreases toward the distance from the working fluid inlet pipe 17. As a result, a variation in the internal pressure occurs between the tubes 12 communicating with the tank 15, and the amount of working fluid passing through each tube 12 is not evenly distributed, resulting in a decrease in heat exchange efficiency. do.

Therefore, in the third embodiment, in expanding the inlet portion of the working fluid flow path as described above, the expansion pipe size increases from the tank 15 on the working fluid inlet pipe 17 side to the tank 15 on the distant side. It is formed.

According to this structure, as shown in FIG. 8, the working fluid flow passage 14 communicating with the tank 15 gradually goes from the tank 15 closest to the working fluid inlet pipe 17 to the tank 15 at the distant side. As the inclined inlet is gradually increased, some of the initial working fluid flows vertically through the smaller inlet size and the others gradually flow through the larger inlet size. The flow velocity of the working fluid is uniform in the working fluid flow direction, and the passage amount of the working fluid passing through each tube 12 is also uniformly distributed, thereby improving heat exchange performance.

On the other hand, the first embodiment to the third embodiment described an example of the structure in which the working fluid inlet pipe is connected to the upper tank side, but the same can be applied to the structure in which the working fluid inlet pipe is connected to the lower tank side. In this case, however, since the working fluid inlet pipe is connected to the lower tank side, it is necessary to gradually reduce the expansion pipe size of the inlet portion of the working fluid flow passage 14 in the working fluid flow direction, in contrast to the third embodiment. desirable.

This is because the operating fluid initially introduced through the working fluid inlet pipe connected to the lower tank flows upward in the upper tank direction, and the inlet portion of the working fluid flow path 14 located far from the working fluid inlet pipe by the action of inertial force. Since the working fluid is biased and the working fluid amount is not evenly distributed, the working fluid is uniformly distributed and flows as described above.

In addition, the embodiments of the present invention have been described with respect to both tank-type stacked heat exchanger provided with tanks on both sides of the upper and lower sides, but can also be applied to a single-tank stacked heat exchanger provided with tanks on either of the upper and lower loads.

In addition, embodiments of the present invention can be applied to the case of a heat exchanger in which a tube and a tank are separately formed as described above.

In the heat exchanger having such a structure, the working fluid is distributed to the tube while passing through the working fluid inlet pipe to the upper tank, so that the front end of the tube is prescribed as illustrated in the first to third embodiments. By expanding using the expansion tool of, the flow resistance of the working fluid can be evenly distributed by minimizing the passage resistance of the working fluid as compared to the past.

As described above, according to the present invention, in the stacked heat exchanger having a small inlet portion of the working fluid flow passage communicating with the tank, the passage resistance of the working fluid can be minimized by expanding the inlet portion of the flow passage through which the working fluid flows. Therefore, the flow rate distribution of the working fluid can be made uniform by reducing the inflow loss of the working fluid at the inlet, thereby achieving the optimum heat exchange performance.

In addition, in the present invention, when the inlet portion of the working fluid flow path is enlarged as described above, the expansion pipe size is gradually increased or decreased in the working fluid flow direction, so that the flow speed of the working fluid is made uniform and the hydraulic fluid passes through each tube. The body weight can be kept the same, thereby reducing the temperature deviation between the tubes and increasing the heat exchange efficiency.                     

Although the present invention has been described with respect to the preferred embodiment, the present invention is not limited thereto, and various modifications and applications will be possible to those skilled in the art without departing from the gist of the present invention.

Claims (5)

Hole cups 11a and 11b having slots 11d at upper and lower ends are formed, and at the center, a plurality of plates 11 embossed with a plurality of beads 11c are brazed to each other. A plurality of tubes 12 interconnected by a plurality of layers 12 to form a flow path 14 and upper and lower tanks 15 and 16 through which a working fluid flows, and a corrugate between the stacked tubes 12. In the laminated heat exchanger in which the outermost part of the tube 12 is coupled to the end plate 19 via the heat dissipation fin 13), The inlet portion of the working fluid passage 14 is extended toward the upper tank 15 side, The working fluid flows into the upper tank (15), and the expansion pipe size of the inlet portion of the working fluid flow passage (14) is gradually increased in the working fluid flow direction. delete delete delete Hole cups 11a and 11b having slots 11d at upper and lower ends are formed, and at the center, a plurality of plates 11 embossed with a plurality of beads 11c are brazed to each other. A plurality of tubes 12 interconnected by a plurality of layers 12 to form a flow path 14 and upper and lower tanks 15 and 16 through which a working fluid flows, and a corrugate between the stacked tubes 12. In the laminated heat exchanger in which the outermost part of the tube 12 is coupled to the end plate 19 via the heat dissipation fin 13), The inlet portion of the working fluid passage 14 is extended toward the lower tank 16 side, The working fluid is introduced into the lower tank (16) side, the expansion size of the inlet portion of the working fluid flow passage 14, characterized in that the gradually reduced in the working fluid flow direction.

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