KR200427424Y1 - Corrugated fin for heat exchanger - Google Patents

Abstract

The present invention relates to a heat dissipation fin for a heat exchanger, wherein a heat dissipation fin of a heat exchanger that performs heat exchange between two fluids separated by a solid wall in the form of a square wave so that both sides of the heat dissipation fins are opposite to the plate tube on both sides. It is an object of the present invention to improve the contact area between the plate tube and the heat dissipation fins so that the heat transfer from the plate tube to the heat dissipation fins can be transferred more quickly. The present invention configured for this purpose is a heat exchanger having a heat sink fin (Corrugated fin) is installed in the space between the plurality of plate tubes and the plate tube through which the refrigerant flows to the heat dissipation, the heat radiation fin is a rectangular wave having a planar and side rectangular shape ( Although a certain length is made in the form of a ripple wave, a plurality of ventilation guide pieces at an angle are formed on the upper surface or the lower surface of each plate forming the plane of the heat radiation fin, and the blower is formed by the ventilation guide formed by the ventilation guide piece. It is made of a configuration such that the wind is guided to the lower and upper portion of the heat radiation fin via the ventilation guide piece and the ventilation guide.

Air conditioners, air conditioners, heat exchangers, corrugated fins, heat radiating fins

Description

Heat sink fin for heat exchanger {Corrugated fin for heat exchanger}

1 is a perspective view showing a heat exchanger having a common heat radiation fin is installed.

Figure 2 is a perspective view showing a heat radiation fin for a general heat exchanger.

Figure 3 is a front view showing the installation of a heat radiation fin for a general heat exchanger.

Figure 4 is a perspective view showing the structure of a heat radiation fin for a heat exchanger according to the present invention.

5 is a cross-sectional view showing a structure of a heat radiation fin for a heat exchanger according to the present invention.

Figure 6 is a cross-sectional view showing another structure of the heat radiation fins for heat exchangers according to the present invention.

Figure 7 is a perspective view showing another structure of the heat radiation fins for heat exchangers according to the present invention.

8 is a cross-sectional view of FIG.

9 is a perspective view showing an installation state of the heat dissipation fin for a heat exchanger according to the present invention.

10 is a cross-sectional view showing another structure of a heat radiation fin for a heat exchanger according to the present invention.

[Description of Symbols for Main Parts of Drawing]

100. Heat Exchanger 110. Plate Tube

120. Heat sink fin 122. Flat plate

124. Side plate 200. Ventilation guide

210. Ventilation guide

The present invention relates to a heat dissipation fin for a heat exchanger, and more particularly, the contact surface between the heat dissipation fin and the plate tube of the heat exchanger which performs heat exchange between two fluids separated by a solid wall is improved, and the wind caused by the blower lowers the heat dissipation fin. And relates to a heat dissipation fin for guiding through the upper portion.

In general, a heat exchanger refers to a device that performs heat exchange between two fluids having different temperatures and separated by solid walls. In the narrow sense, a heat exchanger is generally used between two process flows without phase change. Refers to a device for exchanging heat, and broadly includes a cooler, a condenser, and the like. Such heat exchangers are widely used for heating, air conditioning, power generation, cooling, and waste heat recovery.

On the other hand, the types of heat exchanger, first of all, are classified according to the geometrical form of shell & tube heat exchanger, double pipe type heat exchanger, plate type heat exchanger, and air cooler. , Heated Heater and Coil Type Heat Exchanger, Heat Exchanger, Cooler, Condenser, Reboiler, Evaporator , Preheater and Two Phase Flow Heat Exchanger. The following shows the heat sink fin structure of a general cold half heat exchanger.

1 is a perspective view showing a heat exchanger having a general heat dissipation fin, FIG. 2 is a perspective view showing a heat dissipation fin for a general heat exchanger, and FIG. 3 is a front view showing a heat dissipation fin for a general heat exchanger.

Referring to the configuration of a general heat exchanger 10 as shown in Figure 1 is installed at a predetermined interval in the vertical direction a plurality of plate tubes 12, the end plate installed on both sides of the plate tube 12, the refrigerant flows ( 14) a heat dissipation fin 16 installed in the space between the plate tube 12 and between the plate tube 12 and the end plate 14 to radiate heat, and the refrigerant inlet pipe 18a through which the refrigerant is introduced and discharged; It consists of the structure of the refrigerant | coolant discharge pipe 18b.

On the other hand, looking at the configuration of the heat dissipation fins 16 in the configuration of the heat exchanger 10 as described above, the heat dissipation fins 16 has a wave form (zigzag) as shown in FIGS. 12) is installed between. As such, the heat radiation fins 16 installed between the plate tubes 12 dissipate heat transferred from the plate tube 12.

However, the heat dissipation fin of the heat exchanger configured as described above has a waveform structure such as a sawtooth wave or a sine wave, and when it is installed between both plate tubes, a plurality of ends formed on both sides of the heat dissipation fin as shown in FIG. Since there is a line contact on the opposite surface of the plate tube there is a problem that the heat transfer from the plate tube to the heat radiation fin is not properly made.

Therefore, as described above, the heat dissipation of the heat exchanger is not properly performed because a plurality of ends formed on both sides of the heat dissipation fin are in line contact with each other on the opposite surface of the plate tube, and heat transfer from the plate tube to the heat dissipation fin is not performed properly. have. That is, there exists a problem that the heat radiating effect of a heat exchanger falls.

The present invention has been made to solve the various problems of the prior art, to provide a heat dissipation fin for the heat exchanger to improve the contact surface between the heat sink and the plate tube of the heat exchanger that performs heat exchange between the two fluids separated by a solid wall. There is a purpose.

In addition, the technique according to the present invention has an object to provide a heat dissipation fin for the heat exchanger to guide the wind by the blower through the lower and upper portion of the heat dissipation fin.

The present invention configured to achieve the above object is as follows. That is, the heat dissipation fin for the heat exchanger according to the present invention is installed in the space between the plurality of plate tubes and the plate tube in which the refrigerant flows heat exchanger (Corrugated fin) is provided with heat radiation,

The heat dissipation fin is formed in the form of a square wave in which the flat plate and the side plate are bent at a constant interval continuously, and the side plate is formed in surface contact with the plate tube.

At this time, the heat radiating fin is formed in a uniform zig-zag form a flat plate that is continuous at regular intervals through vertical compression.

In addition, each plate of the heat radiation fin is formed with a plurality of ventilation guides for allowing the wind by the blower to the upper and lower and the ventilation guide piece for guiding the direction of the wind through each ventilation guide.

At this time, the above-described ventilation guide piece is formed in two groups consisting of the forward and reverse direction of the blowing direction for each flat plate is guided from the upper or lower to the lower or upper by the first guide ventilation guide piece, the second group of It is better configured to be guided from the bottom or top to the top or bottom by the ventilation guide piece.

Hereinafter, a heat dissipation fin for a heat exchanger according to a preferred embodiment of the present invention will be described in detail.

Figure 4 is a perspective view showing the structure of the heat dissipation fin for heat exchanger according to the present invention, Figure 5 is a sectional view showing the structure of the heat dissipation fin for heat exchanger according to the present invention, Figure 6 is a sectional view showing another structure of the heat dissipation fin for heat exchanger according to the present invention, 7 is a perspective view showing another structure of the heat dissipation fin for the heat exchanger according to the present invention, Figure 8 is a sectional view of Figure 7, Figure 9 is a perspective view showing the installation state of the heat dissipation fin for heat exchanger according to the present invention, Figure 10 is a heat exchange according to the present invention This is a cross-sectional view showing another structure of the heat radiation fin for use.

4 to 10, according to the present invention, in the form of the heat dissipation fin 120 constituting the heat exchanger 100, the flat plate 122 forming a plane and the side plate 124 forming a side are rectangular in shape. It is constructed in the form of a square wave. In this case, the square wave is also called a rectangular wave or square wave, and the heat dissipation fin 120 according to the present invention has a time axis on an x axis and an amplitude axis on a y axis. When the grab waveform is displayed, the flat plate 122 and the side plate 124 are formed in a rectangular shape like a square wave, which is a rectangular electric signal.

As described above, the heat dissipation fin 120 for a heat exchanger according to the present invention having a flat plate 122 forming a plane and a side plate 124 forming a side in the form of a rectangular wave having a rectangular shape is shown in FIGS. 4 and 10. As shown is installed between the plate tube (110). At this time, the heat dissipation fins 120 installed between the plate tubes 110 have side plates 124 formed upside down on both sides of the heat dissipation fins 120 on the opposite surfaces of the two plate tubes 110 on both sides.

As described above, the heat dissipation fin 120 according to the present invention has a flat plate 122 and a side plate 124 forming a side in the form of a rectangular wave having a rectangular shape, as shown in FIGS. 4 and 10. As shown in the case of installing the heat dissipation fin 120 of the present invention between the plate tube 110, the outer surface of the side plate 124 of the heat dissipation fin 120 is opposed to the plate tube 110 located on both sides of the heat dissipation fin 120 The contact area of the heat dissipation fin 120 and the plate tube 110 is improved compared to the prior art.

Therefore, as described above, the heat dissipation fins 120 according to the present invention are installed between the plate tubes 110 so that both side plates 124 of the heat dissipation fins 120 are disposed on the opposite surface of the plate tube 110 through a wider surface. By making the surface contact the heat of the plate tube 110 is more quickly transferred to the heat radiation fins (120).

On the other hand, the heat radiation fins 120 formed in the shape of a square wave can be formed so that the flat plate 122 is formed in a uniform zigzag form at regular intervals through vertical compression as shown in FIG. That is, by pressing the heat radiating fins 120 up and down, the open portions on the opposite side of the side plate 124 are narrowed, and the flat plate 122 is formed in a zigzag shape.

Therefore, according to such a configuration, the vertical spacing of the heat dissipation fins 120 becomes more dense, thereby improving heat dissipation efficiency.

Meanwhile, as described above, the heat dissipation fin 120 for a heat exchanger according to the present invention, which is configured in the form of a square wave having a flat plane and a side surface, has a flat plate 122 that forms the plane as shown in FIGS. 7 to 10. A plurality of ventilation guides 200 formed by the ventilation guide piece 200 and the ventilation guide piece 200 formed at a predetermined angle on each upper or lower surface thereof are formed by the ventilation guide piece 200. Through the ventilation guide 210 to be blown by the blower (not shown) is configured to be guided to the lower and upper portion of the heat dissipation fin 120 via the ventilation guide piece 200 and the ventilation guide 210.

As described above, the technique according to the present invention forms a plurality of ventilation guide pieces 200 and ventilation guides 210 at a predetermined angle on the upper or lower surface of the flat plate 122 of the heat dissipation fins 120. Through the ventilation guide piece 200 and the ventilation guide 210 to guide the lower and the upper portion of the flat plate 122 of the heat dissipation fin 120 by the wind blower guide 200 and the ventilation guide 210 In the process of rubbing the surface of the heat dissipation fins 120 via the air to heat the heat radiating from the heat dissipation fins 120 more quickly to facilitate the heat dissipation of the heat dissipation fins 120.

In other words, the technology according to the present invention forms a plurality of ventilation guide piece 200 and the ventilation guide 210 at a predetermined angle on the upper surface or the lower surface of the flat plate 122 of the heat dissipation fin 120 is blown by the blower By guided to the lower and upper portion of the heat dissipation fin 120 through the ventilation guide piece 200 and the vent guide 210 to allow the wind caused by the blower to pass through the surface of the heat dissipation fin 120 for a longer time. The heat dissipation will be made faster.

As described above, the heat dissipation fin 120 having the ventilation guide piece 200 and the ventilation guide 210 formed thereon may be applied to the heat dissipation fin 120 illustrated in FIG. 6.

That is, the ventilation guide piece 200 by pressing the top and bottom of the heat radiation fin 120 in a state in which the ventilation guide piece 200 and the ventilation guide 210 formed on the flat plate 122 of the heat radiation fin 120 formed in a square wave shape. And the flat plate 122 formed with the ventilation guide 210 is formed in a zigzag form.

Referring to the technology according to the present invention in more detail as follows. First, looking at the configuration of the heat dissipation fin 120 according to the present invention, the flat plate 122 and the side plate 124 is made of a rectangular shape is made of a predetermined length in the form of a square wave (矩 波) of alternately bent structure of the heat dissipation fin 120 By forming a plurality of ventilation guide pieces 200 of a predetermined angle on the upper surface or the lower surface of each flat plate 122 forming a plane by a blower through the ventilation guide 210 formed by the ventilation guide piece 200 It is made of a configuration such that the wind is guided to the bottom and top of the flat plate 122 of the heat dissipation fin 120 via the ventilation guide piece 200 and the ventilation guide 210.

The ventilation guide piece 200 of the heat dissipation fin 120 of the present invention configured as described above is formed in the blowing direction of the blower on the upper or lower surface of the flat plate 122 of the heat dissipation fin 120, but with respect to the blowing direction of the blower. It is formed in two groups in the opposite direction to the corresponding direction and the wind by the blower is guided from the upper or lower to the lower or upper through the first guide of the ventilation guide 200, the second guide of the ventilation guide 200 It is configured to be guided from the lower or upper to the upper or lower through).

Meanwhile, as described above, the flat plate 122 and the side plate 124 are formed in a rectangular shape, and have a predetermined length in the form of a square wave having an alternately bent structure, while the top or bottom of each of the flat plates 122 forming a plane is formed. The heat radiation fins 120 formed of a plurality of ventilation guide pieces 200 and a plurality of ventilation guides 210 formed by a predetermined angle on the surface are installed at regular intervals in a vertical direction, and a plurality of plate tubes 110 in which refrigerant flows. It is installed on the space between the two sides are in contact with the opposite surface of the plate tube 110 to dissipate the heat transferred from the plate tube 110.

In the configuration of the heat dissipation fins 120 configured as described above, the wind caused by the blower is guided upward and downward on each of the flat plates 122 of the heat dissipation fins 120, as shown in FIG. A plurality of ventilation guide pieces 200 and ventilation guides 210 are formed at a predetermined angle called a luba angle. At this time, the ventilation guide piece 200 is formed in the blowing direction of the blower.

As described above, the ventilation guide piece 200 formed at a predetermined angle on the upper surface or the lower surface of the plate 122 forms a plurality of cutting lines at a predetermined interval on the surface of the plate 122, and then two cutting lines. The ventilation guide piece 200 therebetween is inclined at an angle so that the ventilation guide 210 is formed. At this time, the above-described ventilation guide piece 200 is formed in two groups in a direction opposite to the direction corresponding to the blowing direction of the blower as shown in Figure 8 so that the wind caused by the blower guide guide piece 200 After being guided from the top or bottom of the flat plate 122 to the bottom or top through the ventilation guide 210), the flat plate 122 through the ventilation guide piece 200 and the ventilation guide 210 of the second group It is guided from the bottom or top of the top or bottom.

In the configuration as described above, the heat radiation fin 120 according to the present invention formed a plurality of ventilation guide piece 200 and the ventilation guide 210 is a wind blower by the blower guide piece 200 and the ventilation guide 210 By passing through the surface of the heat dissipation fin 120 for a longer time in the process of guiding to the lower and upper portions of the flat plate 122 so that the heat dissipation of the heat dissipation fin 120 can be made faster.

The present invention is not limited to the above-described embodiments and can be carried out in various modifications within the range allowed by the technical idea of the present invention.

As described above, according to the present invention, the side plate of the heat dissipation fin has an effect of allowing the heat transfer from the plate tube to the heat dissipation fin more quickly by improving the contact surface through the surface contact with the plate tube.

In addition, there is an effect to improve the heat radiation of the heat radiation fins by the wind guided by the blower to the lower and upper portion of the heat radiation fins through the ventilation guide and the ventilation guide piece of the heat radiation fins.

Claims (4)

In a heat exchanger having a heat sink fin (Corrugated fin) is installed in the space between the plurality of plate tubes and the plate tube to the refrigerant flow to radiate heat, The heat dissipation fin is a heat dissipation fin for heat exchanger, characterized in that the plate and the side plate is formed in the form of a square wave bent at a predetermined interval continuous. The heat dissipation fin according to claim 1, wherein the heat dissipation fin is formed in a uniform zigzag form in which a flat plate is continuous at regular intervals through vertical compression. According to claim 1 or claim 2, wherein each of the heat sink fins are formed with a plurality of ventilation guides for directing the wind by the blower to the upper and lower and the ventilation guide piece for guiding the direction of the wind through each of the ventilation guides Heat dissipation fin for heat exchanger, characterized in that made. According to claim 3, The ventilation guide pieces are formed in two groups consisting of the forward direction and the reverse direction of the blowing direction for each flat plate is guided from the top or bottom to the bottom or top by the first group of ventilation guide pieces, Heat dissipation fin for heat exchanger, characterized in that configured to be guided from the bottom or top to the top or bottom by the ventilation guide piece of the first group.

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