KR19990012511A - Heat exchanger of air conditioner - Google Patents

Abstract

The heat exchanger of the air conditioner according to the present invention includes a plurality of plate fins arranged in parallel at regular intervals such that air flows therebetween, and heat exchanges the airflow contacting the plate fins with a predetermined temperature while the fluid flows therein. In the heat exchanger of the air conditioner consisting of a plurality of heat pipes inserted at right angles to the flat fins, the flat fins, the inclined opening in the flow direction of the air flow at the same time and at the top and bottom of the heat transfer tubes to wrap in a radial shape around the heat pipes It is characterized by comprising a plurality of louver portions provided between, and a plurality of bead portions provided in the center between the upper and lower sides of the heat transfer pipes and the front and rear sides of the heat transfer pipes, so that the flow of airflow can be increased to promote turbulence. Of course, not only can the heat transfer performance and heat transfer efficiency be improved, but also the louver section is installed. It is possible to increase the area to the maximum, and to increase the surface area of the plate fin by a plurality of bead portion at the same time to easily drain the condensate generated in the heat transfer tube as well as to minimize the dead zone.

Description

Heat exchanger of air conditioner

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat exchanger of an air conditioner, and in particular, a plurality of louver-type season groups and beads are formed on a flat fin, and flow streams (eg, air) passing through them are turbulent and mixed. The present invention relates to a heat exchanger of an air conditioner, which improves heat exchange performance and at the same time reduces the exponential region (e.g., cross-flow region) generated behind the plurality of heat transfer tubes.

The heat exchanger of the air conditioner according to the related art is similar to a plurality of flat fins 1 arranged in parallel at regular intervals as shown in FIG. It consists of the heat exchanger tubes 2 arrange | positioned in the arranged shape, and an airflow flows in the direction of the arrow which shows between the said several flat plate fins 1, and performs heat exchange with the fluid in the heat exchanger tube 2. As shown in FIG.

And, as shown in FIG. 2, the thermal fluid characteristics around the plate fin 1 are thickened in proportion to the square root of the distance from the inflow portion of the airflow in the thickness of the temperature boundary layer 3 on the heat transfer surface of the plate fin 1. Since the airflow-side heat transfer rate increases, the distance from the inflow portion of the airflow increases, and the temperature decreases significantly, and the heat transfer performance of the heat exchanger is low.

In addition, as shown in FIG. 3, the heat fluid characteristics around the heat exchanger tube 2 are characterized by an angle of 71 ° -80 from a blocked point on the surface of the heat transfer tube 2 when the low wind speed air flows in the direction of the arrow in the heat transfer tube 2. Since the flow is peeled off at °, and the crossflow zone 4 indicated by the oblique line is formed at the rear part of the heat transfer pipe 2, the heat transfer performance of the airflow side in this crossflow zone 4 is remarkably lowered, so that the heat transfer performance as the heat exchanger is low. Had a flaw.

Therefore, the conventional heat exchanger of the air conditioner of Korean Patent Application No. 96-27642 (application date: July 7, 1996) has been proposed by the present applicant to solve this problem.

That is, in the heat exchanger, the louver type season group 10, as shown in Figs. 4 and 5, the air flow flowing to the back surface and the surface of the plate fin 1 between the plurality of heat transfer tubes (2). First and second louvers installed in diagonal directions protruding to the rear surface and the surface of the flat fin 1 with a shape symmetrical with each other in front and bottom of the heat transfer pipe 2 so as to be turbulent and mixed when passing from the front to the middle Turbulence and mixing again when the air stream diffused by the sections 20, 30 and the first and second louver sections 20, 30 passes from mid to rear with respect to the plurality of heat pipes 2 The third and the diagonally protruding to the rear surface and the surface of the flat fin 1, respectively, having a shape symmetrical with each other in the upper and lower rear side of the heat pipes 2 so as to reduce the cross-sectional area generated behind the heat pipes 2; Fourth louver parts 40 and 50 are comprised.

At this time, the first and second louver portions 20 and 30 have a left end projecting to the rear surface of the flat plate pin 1 so as to be opened at right angles in the flow direction of the air flow passing through the flat plate pin 1 and at the same time. The stage is provided by cutting in an oblique direction protruding to the surface of the flat fin 1, and the third and fourth louver portions 40, 50 are opposed to the flow of air flow passing through the flat fin 1 The left end protrudes to the surface of the flat plate pin 1 so as to be opened at right angles in the direction, and the right end protrudes to the back surface of the flat plate pin 1 by cutting.

Upper ends of the first and third louver parts 20 and 40 are radially disposed along the circumference at the same radius with the outer peripheral surface of the lower side of the heat transfer tubes 2 and the predetermined base part 60, and the second And the lower ends of the fourth louver portions 30 and 50 are radially disposed along the circumference at the same radius with the upper outer peripheral surface of the heat transfer tubes 2 and the predetermined base 60.

The first and third louver portions 20 and 40 and the second and fourth louver portions 30 and 50 are vertically symmetrically installed with a predetermined base portion 60 parallel therebetween, And the second louver portions 20 and 30 and the third and fourth louver portions 40 and 50 are arranged symmetrically with a predetermined base portion 60 therebetween.

The first to fourth louver portions 20, 30, 40, and 50 have a plurality of seasons 70, 71, 72, 73, 74, and 75 which are continuous in the horizontal direction, respectively. , 71, 72, 73, 74 and 75 are installed by cutting without each other.

In the drawing, reference numeral 80 denotes between the upper and lower sides of the heat pipes 2 so as to increase the surface area of the plate fin 1 and at the same time have a drainage guide function through which the condensed water generated in the heat pipes 2 can flow down well. The bead portion bent by the beading process in the vertical direction to the center.

That is, the bead portion 80 is a base between the first and second louver portions 20 and 30 and the third and fourth louver portions 40 and 50 as shown in FIGS. 4 and 5. It is bent to the rear surface of the flat fin (1) to be installed in the portion 60, the upper and lower ends are installed in a radial shape with the upper and lower outer peripheral surface and the predetermined base portion 60 of the heat transfer tubes (2). It is provided on the same extension line of the season group 10.

However, according to the heat exchanger of the conventional air conditioner configured as described above, the first to fourth louver portions 20, 30, 40, and 50 are obliquely disposed between the upper and lower sides of the heat transfer pipe 2 at inclined angles which are symmetrically left and right. Although the cutting process is performed in the direction, the first to fourth louver portions 20, 30, 40, and 50 of this structure are each cut into six seasons 70, 71, 72, 73, at predetermined positions of the flat plate pin 1. 74 and 75, the number of the first and second louver portions 20 and 30 and the third and fourth louver portions 40 and 50, as shown in Figs. The angle of inclination was designed to be 49 ° wide, and the season height (H) was low and the season width (W) was very narrow.

Accordingly, the front and rear sides of the heat transfer pipe 2 have a wide interval L, in which the first to fourth louver portions 20, 30, 40, and 50 are not installed, so that the pressure drop amount is small, but the heat transfer performance is relatively low. This greatly falls, there is a problem that not only can not promote turbulence as the flow of the air flow is low, but also the heat transfer efficiency is significantly reduced.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to minimize the number of seasons to sufficiently increase the height of the season to increase the flow of air flow and promote turbulence, as well as heat transfer performance And the installation area of the louver, such as to increase the height of the season and increase the width of the season, by allowing the louver to be installed at a radial angle of about 29 ° around the heat pipe. It is to provide a heat exchanger of an air conditioner that can be widened to promote turbulence and increase heat transfer efficiency.

It is another object of the present invention to provide a heat exchanger for an air conditioner to increase the surface area and increase the strength of the flat plate fins by providing bead portions between the heat transfer tubes and the heat transfer tubes, respectively, and at the same time, respectively. It is.

The heat exchanger of the air conditioner according to the present invention made to achieve the above object, a plurality of flat fins arranged in parallel at a predetermined interval so that the air flow flows therebetween, and the air flow in contact with the flat fins while the fluid flows inside In the heat exchanger of the air conditioner consisting of a plurality of heat transfer tubes inserted into the plate fins at right angles to heat the heat to a predetermined temperature, the plate fins, while being inclined opening in the flow direction of the air flow in the radial direction along the circumference of the heat transfer tube And a plurality of louver portions installed between upper and lower sides of the heat transfer tubes, and a plurality of bead units installed at the center between the upper and lower sides of the heat transfer tubes and the front and rear sides of the heat transfer tubes.

1 is a perspective view showing a conventional heat exchanger,

FIG. 2 is an enlarged view illustrating a thermal fluid characteristic around the plate fin in FIG. 1;

Figure 3 is an enlarged view showing the thermal fluid properties around the heat pipe in Figure 1,

4 is a plan view showing a plate fin of another conventional heat exchanger,

5 is a cross-sectional view taken along line A-A of FIG. 4;

Figure 6 is a plan view showing a flat fin of the heat exchanger according to the present invention,

7 is a cross-sectional view taken along line B-B of FIG. 6;

8 is a detailed view of part C of FIG. 6;

9 is a cross-sectional view showing the bead portion of the present invention.

Explanation of symbols on the main parts of the drawings

1: flat plate fin 2: heat pipe

100: louver season season 160: base

120, 130, 140, 150: first to fourth louver portions

170, 171, 172, 173: seasons

180, 181, 182: first to third bead portions

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the drawings, the same components as those in the related art are denoted by the same name and the same reference numerals, and detailed description thereof will be omitted.

For reference, reference numeral 100 in the drawing allows the flow of airflow flowing to the back and the surface of the plurality of flat fins 1 to be turbulent and mixed, thereby reducing the cross-flow area generated behind the plurality of heat pipes 2. In order to improve the overall heat transfer performance, the upper and lower circumferential surfaces of the heat transfer pipe 2 are opened in the plate fin 1 with the left and right symmetrical openings in the flow direction of the air flow and the opposite direction of the air flow to the plate fin 1. Represents a plurality of louver season group installed in a radial shape wrapping.

That is, the louver-type season group 100, the air flow flowing to the back surface and the surface of the plate fin (1) as shown in Figure 6 and 7 from the front with respect to the plurality of heat pipes (2). The first and second louver portions 120, which have a shape symmetrical with each other on the front and bottom sides of the heat transfer tube 2 so as to be turbulent and mixed when passing through the middle, and are installed in diagonal directions protruding to the rear surface and the surface of the flat fin 1, respectively. And 130, and the turbulence and mixing are further turbulent and mixed as the mixed airflow diffused by the first and second louver portions 120 and 130 passes from the middle to the rear with respect to the plurality of heat transfer tubes 2. 2) third and fourth louvers each having a shape symmetrical with each other in the upper and lower sides of the heat pipes 2 and diagonally projecting to the rear surface and the surface of the flat fin 1 so as to reduce the cross-sectional area occurring behind them; It consists of parts 140 and 150.

At this time, the first and second louver portions 120 and 130 have a left end projecting to the rear surface of the flat plate pin 1 so as to be opened at right angles in the flow direction of the air flow passing through the flat plate pin 1 and at the same time. The stage is installed by cutting in an oblique direction protruding to the surface of the flat fin 1, and the third and fourth louver portions 140 and 150 are opposed to the flow of air flow passing through the flat fin 1 The left end protrudes to the surface of the flat plate pin 1 so as to be opened at right angles in the direction, and the right end protrudes to the back surface of the flat plate pin 1 by cutting.

Upper ends of the first and third louver parts 120 and 140 are radially disposed along the circumference at the same radius with the outer peripheral surface of the lower side of the heat transfer pipes 2 and the predetermined base part 160, and the second And the lower ends of the fourth louver portions 130 and 150 are radially disposed along the circumference at the same radius with the upper outer peripheral surface of the heat transfer tubes 2 and the predetermined base portion 160.

The first and third louver portions 120 and 140 and the second and fourth louver portions 130 and 150 are vertically symmetrically installed with a predetermined base portion 160 parallel therebetween, And the second louver portions 120 and 130 and the third and fourth louver portions 140 and 150 are symmetrically installed with a predetermined base portion 160 therebetween.

The first to fourth louver parts 120, 130, 140, and 150 are provided with a plurality of seasons 170, 171, 172, and 173 that are continuous in the horizontal direction, respectively. 172 and 173 are installed by cutting without each other.

The season angle χ between the first louver part 120 and the third louver part 140 or between the second louver part 130 and the fourth louver part 150 is perpendicular to the insulator tube 2. In the case of the sum of the left and right in the center line, 26 ° ≤ χ ≤ 32 ° is installed.

In the drawings, reference numerals 180, 181, and 182 increase the surface area of the flat fin 1 and at the same time between the upper and lower sides of the heat transfer tubes 2 so that the condensed water generated in the heat transfer tubes 2 flows to a predetermined position. And first and third bead portions formed by beading processing in the vertical direction on the front and rear sides of the heat transfer pipe 2, respectively.

That is, the first bead part 180 is a side between the first and second louver parts 120 and 130 and the third and fourth louver parts 140 and 150 as shown in FIGS. 8 and 9. It is formed to protrude to the rear surface of the plate fin (1) to be installed in the base portion 160, the upper and lower ends are provided with the upper and lower outer peripheral surface and the predetermined base portion 160 of the heat transfer tubes (2).

The second and third bead parts 181 and 182 protrude to the rear surface of the flat plate pin 1 with the insulating tube 2 and the predetermined base part 160.

Next, the operation and effect of the present invention configured as described above will be described.

When the airflow flows in the arrow S direction shown in FIG. 6, the flow airflow flows in the same diagonal direction to the backside and the surface of the flat plate fin 1, respectively, when it flows between the backside and the surface side of the plurality of flat plate fins 1. Continuously passing through the plurality of protruding first to fourth louver portions 120, 130, 140, and 150 as shown by the solid arrow direction shown in FIG. 7 so that the flow of heat from the heat transfer pipe 2 is smoothly blocked. Turbulent and mixed.

That is, the seasons of the first and second louver portions 120 and 130 installed in the upper and lower fronts of the heat transfer tubes 2 so that a part of the air flow flowing to the rear surface side of the flat fin 1 is opened at right angles in the flow direction of the air flow. The heat exchanger tube (2) is mixed with the original air flow flowing to the surface side of the plate fin (1) through the (170, 171, 172, 173) and simultaneously flown to the surface side, and turbulent by the mixing phenomenon of these air streams (2). At the same time, a larger amount of airflow is stagnated from the front to the middle of the heat transfer, and the heat transfer performance is enhanced to achieve a high heat exchange around the heat transfer tube (2).

Moreover, the seasons 170 and 171 of the 2nd and 3rd louver parts 140 and 150 provided in the upper and lower rear part of the heat exchanger tubes 2 so that a part of the turbulent airflows may be opened at right angles in the direction opposite to the flow of the airflow. , 172, 173 flows to the back surface side of the plate fin 1 and is mixed with the original air flow flowing to the back surface side and turbulent again by the mixing phenomenon of the airflow tube 2, thereby The flow of the flow stream from the rear to the rear is smoothly turbulent and mixed along the circumferential surface of the heat pipe (2) is transmitted to the rear side of the heat pipe (2).

In this case, since the first to fourth louver portions 120, 130, 140, and 150 are provided in a radial shape with a predetermined base portion 160 with respect to the upper and lower outer circumferential surfaces of the heat transfer tubes 2, the first to fourth louver portions 120, 130, 140, and 150 are provided. The turbulent air passing through the louver portions 120, 130, 140, and 150 passes more toward the rear of the heat pipe 2, thereby reducing the cross-sectional area generated behind the heat pipes 2 to the minimum area, as well as the heat pipe 2. In the rear of the field will increase the heat transfer effect.

That is, since the number of seasons 170, 171, 172, and 173 of the first to fourth louver parts 120, 130, 140, and 150 is smaller than that of the related art, the pressure drop is large, but the heat transfer performance is relatively increased. In addition, as the flow of air flows large, turbulence can be promoted and heat transfer efficiency can be improved.

In addition, the first to fourth louver portions 120, 130, 140, and 150 have an outer circumferential surface and a predetermined base portion 160 with respect to the upper and lower sides of the heat transfer tubes 2, and 26 ° along the circumference with the same radius. Since it is installed inclined to have a radial season angle (χ) of ≤ χ ≤ 32 °, it is possible to increase the season height (H) of the louver-type season group 100 as shown in FIG. Since the interval (P) covering the front and rear of the heat transfer pipe (2) can be narrowed by that amount, the installation area of the first to fourth louver parts (120, 130, 140, 150) is expanded to the maximum to further promote turbulence of airflow. It can of course increase the heat transfer efficiency.

On the other hand, the first to third bead portions 180, 181, 182 are provided in the flat plate 1 by the beading process in the center and the front and rear sides of the heat transfer pipes 2 between the upper and lower sides of the heat transfer tubes 2, respectively. As a structure, the surface area of the flat fin 1 is increased and at the same time, the condensed water generated in the heat transfer pipe 2 flows well to a predetermined position, and in particular, the air flow passing through the second bead portion 181 is shown in FIG. As described above, the front of the heat transfer tube 2 is turbulent in the vertical direction and flows along the periphery of the heat transfer tube 2, and when it reaches the rear of the heat transfer tube 2, it hits the third bead part 182 to cause the heat transfer tube ( This will minimize the cross-flow area that occurs behind 2) and also increase the heat transfer efficiency.

As described above, according to the heat exchanger of the air conditioner according to the present invention, since the first to fourth louver portions have a smaller number of seasons than the conventional ones, the height of the season is increased and the width of the season is widened. The season interval that wraps is narrowed by that, which can increase the flow of airflow, thereby promoting turbulence, as well as improving heat transfer performance and heat transfer efficiency.

In addition, since the first to fourth louver portions are installed at radial interval angles (χ) of 26 ° ≤ χ ≤ 32 ° along the periphery with the same radius with respect to the upper and lower sides of the heat transfer tubes, with the same outer circumferential surface. It is effective to increase the installation area to the maximum.

In addition, since the first to third bead portions are provided by beading, respectively, in the center and between the upper and lower sides of the heat transfer tubes, the flat plate fins increase the surface area of the flat fins. It is easy to drain the condensate generated in the heat pipe, minimize the cross-flow area, and increase the heat transfer efficiency.

Claims (3)

A plurality of flat fins arranged in parallel at regular intervals so that the air flows therebetween, and a plurality of heat transfer tubes inserted at right angles to the flat fins to heat exchange the air flow contacting the flat fins with a predetermined temperature while the fluid flows therein. In the heat exchanger of the configured air conditioner, The flat plate pin, a plurality of louver portions provided between the upper and lower sides of the heat transfer tubes so as to be inclined to open in the flow direction of the air flow and to surround the heat transfer tubes in a radial shape; Heat exchanger of the air conditioner comprising a plurality of bead portion provided in the center between the upper and lower sides of the heat transfer pipe and the front and rear sides of the heat transfer pipe. The method of claim 1, The season angle (χ) of the plurality of louver portion is a heat exchanger of the air conditioner, characterized in that the sum of the left and right in the vertical center line of the heat pipe is 26 ° ≤ χ ≤ 32 °. The method of claim 1, And the plurality of bead portions are beaded to the back surface of the plate fin with a predetermined base portion around the heat transfer tube.