KR20110072005A - The heat exchanger - Google Patents

Abstract

PURPOSE: A heat exchanger is provided to make air flow smooth by making air flow through a wide space in a heat radiating surface. CONSTITUTION: A heat exchanger comprises a plurality of tubes, a plurality of louver fins(400) and a plurality of louvers(411). The louver fins are installed between the tubes. One heating radiating surface(410) of one side and another heat radiating surface of the other side of the louver fin forms a wedge shape. The louver fins are twisted from the flow direction of air. The louvers make a slope so that air flowing to the outside of the heat radiating surface flows into the heat radiating surface. The louvers are formed on the surfaces of the louver fins. The louvers make contact with air passing through the louver fins.

Description

Heat Exchanger {THE HEAT EXCHANGER}

The present invention relates to a heat exchanger for heat-exchanging internal circulating fluid and external air, such as an evaporator, a condenser or a radiator of an automobile air conditioner, and more particularly, to a heat exchanger having louver fins.

Recently, as the interest in the environment and energy in the automobile industry is increasing, researches for improving fuel efficiency have been conducted. Above all, it is necessary to satisfy various requirements such as pedestrian protection laws and various consumer needs, thereby reducing the weight In the meantime, research and development for miniaturization and high functionalization are being carried out steadily.

Heat exchanger fins are a major component of heat exchangers that increase heat exchange efficiency by increasing the area in contact with air interposed between adjacent tubes. Research and development have been conducted to maximize heat dissipation performance even in these heat exchanger fins.

1 is a view illustrating a general form of a conventional heat exchanger, and connecting the upper header tank 10 and the lower header tank 20 and the upper header tank and the lower header tank formed side by side at a predetermined distance, It can be seen that it comprises a plurality of tubes 30 arranged in parallel, a plurality of pins 40 interposed between the tubes.

Louver fin is to increase the heat exchange area by flowing air between the upper and lower layers of the fin in order to maximize heat exchange efficiency. The louver fin is formed on the heat dissipating surface of the fin.

3 illustrates a conventional louver fin provided in a conventional vehicle heat exchanger.

These louver fins are designed to increase heat exchange efficiency between the circulating fluid and the air in the tube by contacting the tube through which the circulating fluid flows and heat-exchanging with the air in contact with the surface. The louver fin has high thermal conductivity and a specific surface area. The larger) is, the higher the heat exchange efficiency.

Therefore, the louver fin is usually made of a metal having a high thermal conductivity and easy to mold, such as aluminum, and in particular, a louver fin is made of a thin plate structure having a waveform that can maximize the specific surface area without resisting the flow of the fluid.

In addition, a portion of each of the heat dissipating surfaces forming a wave shape is cut and then the cut portion is bent at an angle with respect to the air flow direction to induce air incident on the louver pin to cross-flow through the cut gap. Louvers are formed to be arranged at equal intervals along the air flow direction.

That is, the air flows in a curve along the louver direction.

Figure 4 shows the flow of air by the conventional louver pin.

The louver fin of such a structure affects the heat exchange efficiency of the heat exchanger according to the inclination angle of the louvers formed on each heat dissipation surface, the density of the louver fins to the heat exchanger volume, or the number of waveforms.

However, the conventional louver fin has a structure in which air flow becomes complicated, and thus the pressure drop amount is large, thereby increasing the capacity of the louver fin or lowering the angle of the inclination angle of the louver.

However, there is a limit in reducing the pressure drop because there is a limit in increasing the capacity of the louver pin or lowering the angle of the inclination angle of the louver, there was a problem that the effect does not meet expectations.

The present invention is to solve the above problems, and more particularly, the object of the present invention is to provide a heat exchanger having a louver fin with a smooth flow of air because the pressure drop is not large.

In the present invention, each of the heat dissipation surface on which the louver is formed is not formed in parallel, but is characterized by a predetermined angle so that the space formed between the heat dissipation surface adjacent to the heat dissipation surface is gradually narrowed. The inclined angle of the air is formed so that the air flowing out of the heat dissipation surface can flow into the heat dissipation surface, so that the flowed air enters the large space between the heat dissipation surface and the heat dissipation surface and moves on the outside of the heat dissipation surface. It enters the inside of the heat surface and exits to a large space so that the air flows smoothly.

The heat exchanger of the present invention includes a plurality of tubes, a plurality of louver fins installed between the tubes, and a plurality of louvers formed on the surface of the louver fins so as to be in contact with air passing through the louver pins. The heat exchanger, and the louver fin is characterized in that the mutually fixed angle relative to the air flow direction so as to form a wedge shape of one heat dissipation surface and the other heat dissipation surface adjacent to the one heat dissipation surface.

In the present invention as described above, the angle at which the heat dissipation surface is twisted is preferably 2 to 5 ° based on when the heat dissipation surface and the heat dissipation surface are horizontal.

The louver fin provided in the heat exchanger of the present invention is interposed between a plurality of tubes, and a plurality of louvers in a scale shape on each heat dissipating surface forming a corrugated sheet and forming a wave form an inclination angle. Each of the heat dissipating surfaces is turned at an angle toward the heat dissipating surface facing each other so that the shape of the space formed between the heat dissipating surfaces adjacent to the heat dissipating surface outside becomes narrower toward the outflow direction of air. The angle of inclination is formed so that air flowing outward of the heat dissipation surface can flow into the heat dissipation surface.

Therefore, when air flows into the louver fin, it enters a large space and in the process of moving on the outside of the heat dissipation surface, it enters the inside of the heat dissipation surface and exits through the large space inside the heat dissipation surface, so the air flows smoothly. There is this.

As a result, even in a heat exchanger having a small heat transfer area, the thickness of the heat exchanger can be increased while keeping the pressure drop on the air side low.

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings.

However, the accompanying drawings are only examples to illustrate the technical idea of the present invention in more detail, and thus the technical idea of the present invention is not limited to the accompanying drawings.

1 is a schematic view showing a general form of a conventional vehicle heat exchanger.

In addition, Figure 2 is a schematic diagram for explaining the installation structure of the tube and fin in a conventional vehicle heat exchanger.

3 is a perspective view for explaining a conventional louver pin.

4 is a schematic diagram for explaining the flow of air through a conventional louver pin.

5 is a perspective view showing the louver fin provided in the heat exchanger of the present invention.

6 is a plan sectional view of the louver fin for explaining the flow of air via the rubber fin provided in the heat exchanger of this invention.

The louver fin 400 provided in the heat exchanger of the present invention is interposed between a plurality of tubes 30 forming a flow path of the internal circulating fluid of the heat exchanger in order to enlarge the heat exchange area with external air as in the prior art. .

In addition, a plurality of louvers 411 in the form of scales on each of the heat dissipating surface 410 of the wave form of a thin plate and forming a wave form an inclination angle.

However, the present invention is to provide a heat exchanger having a louver fin with a smooth flow of air because the pressure drop is not large.

To this end, in the present invention, each room so that the shape of the space 420 formed between each of the heat dissipating surface 410 and the neighboring heat dissipating surface 410 is narrowed toward the direction of the outflow of air. Opening surface 410 is to be turned at a predetermined angle toward the heat dissipating surface 410 facing.

That is, the louver fin 400 has a predetermined angle (α) to each other relative to the air flow direction so that one heat dissipation surface 410 and the other heat dissipation surface 410 adjacent to the one heat dissipation surface 410 form a wedge shape. will be.

The inclination angle of the plurality of louvers 411 formed on the heat dissipation surface 41 is formed such that air flowing outward of the heat dissipation surface can be introduced into the heat dissipation surface.

Such a structure is introduced into a wide space when air is introduced into the louver fin 400, and enters the inside of the heat dissipating surface 410 in the process of moving on the outer side of the heat dissipating surface 410, thereby The air flows smoothly because it escapes through the large inner space.

That is, in the form of a thin wave, so that the shape of the space 420 formed between each of the heat dissipation surface 410 and the neighboring heat dissipation surface 410 so as to become narrower toward the air flow direction Each heat dissipation surface 410 is a shape that is twisted at a predetermined angle toward the heat dissipation surface 410 facing each other when the shape of the space 420 becomes narrower toward the outflow direction of air when viewed from the outside of the heat dissipation surface When viewed from the inside of the heat plane, the shape is widened in the direction of the outflow of air.

Therefore, the air flowing into the louver fin 400 flows into the wide place and exits through the wide place, and the air moving on the outside of the heat dissipating surface 410 is smoothly introduced into the heat dissipating surface 410. .

Because of this, the air is to smoothly pass through the louver pin 400.

In the present invention, the heat dissipation surface 410 of the louver fin 400 may be extended in a form close to the vertical as shown in the accompanying drawings, the heat dissipation surface 410 like a general fin including a conventional louver fin It may be angled toward the lower point of the waveform.

However, suitable for the louver pin of the present invention is that the heat dissipation surface 410 is extended in a form close to the vertical as in the accompanying drawings.

The space between the heat dissipating surface and the heat dissipating surface is formed because the shape of the space 420 formed between the heat dissipating surface 410 adjacent to each other outside the heat dissipating surface 410 becomes narrower toward the outflow direction of air. This does not have to be wide.

This is because the larger the gap between the heat dissipation surface 410 and the heat dissipation surface 410, the less the number of the heat dissipation surface 410 is, and the heat exchange efficiency is inevitably lowered.

Therefore, it is preferable to allow the heat dissipation surface 410 to extend in a form close to the vertical so that the number of the heat dissipation surface 410 is located in a smaller space.

In the present invention, in consideration of heat exchange efficiency, the angle α at which the heat dissipation surface 410 is distorted is preferably 2 to 5 ° based on when the heat dissipation surface and the heat dissipation surface are horizontal (see FIG. 6).

1 is a schematic view showing a general form of a conventional vehicle heat exchanger

Figure 2 is a schematic diagram for explaining the installation structure of the tube and fin in a conventional vehicle heat exchanger

A: Tube and pin are arranged

B: A-A section

3 is a perspective view for explaining a conventional louver pin

Figure 4 is a schematic diagram for explaining the flow of air through the conventional louver pin

Figure 5 is a perspective view showing a louver fin provided in the heat exchanger of the present invention

6 is provided with a heat exchanger of the present invention Planar cross-sectional view of the louver pin to explain the flow of air through the louver pin

<Explanation of symbols for main parts of drawing>

10, 20. Header tank 30. Tube

40.Pin 400.Louver Pin

410. Heat sink 411. Louver

420. Space

Claims (3)

A plurality of tubes 30, a plurality of louver fins 400 installed between the tubes 30, and a surface of the louver fins 400 to be in contact with air passing through the louver fins 400. In the heat exchanger comprising a plurality of louvers (411) formed in, The louver fin 400 has a predetermined angle to each other relative to the air flow direction so that one heat dissipation surface 410 and the other heat dissipation surface 410 adjacent to the one heat dissipation surface 410 form a wedge shape. , heat transmitter. The method of claim 1, The inclination angle of the plurality of louvers (411) is characterized in that the air flows to the outside of the heat dissipation surface (410) is formed to be introduced into the heat dissipation surface (410), heat exchanger. The method of claim 1, The heat dissipation surface 410 is an angle of twist is characterized in that the heat dissipation surface 410 and the heat dissipation surface 410 is 2 to 5 ° based on the horizontal, heat exchanger.

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