KR101250753B1 - Radiator - Google Patents

Abstract

The present invention relates to a radiator, and in more detail, the present invention is to expand the width of the header tank by reducing the width of the header tank is formed in both ends of the tube is narrowed in the width direction of the tube and widened in the height direction of the tube And a radiator capable of providing a numerical value of expansion to optimize internal flow.

Description

Radiator {RADIATOR}

The present invention relates to a radiator, and in more detail, the present invention is to expand the width of the header tank by reducing the width of the header tank is formed in both ends of the tube is narrowed in the width direction of the tube and widened in the height direction of the tube And a radiator capable of providing a numerical value of expansion to optimize internal flow.

Generally, in a vehicle equipped with an internal combustion engine, heat generated during operation of the engine is conducted to a cylinder head, a piston, a valve, and the like. As a result, if the temperature of these components excessively increases, the strength of the component decreases due to thermal expansion or deterioration, The life of the engine is shortened and the combustion state is deteriorated, so that knocking or early ignition occurs and the output of the engine is also lowered.

In addition, when the engine is incompletely cooled, the oil film on the inner circumferential surface of the cylinder is broken, and the lubrication function is degraded. Also, the engine oil is deteriorated, which causes abnormal cylinder wear and the piston is fused to the inner wall of the cylinder. Done.

In order to cool such engines, automobiles are usually provided with a water-cooled chiller.

The water-cooled chiller lowers the temperature of the coolant while circulating the cylinder block and the cylinder head by a water pump, and is provided with a radiator, a cooling fan, and a water temperature controller for heat dissipation of the coolant.

That is, the radiator is a device for cooling the coolant of which the temperature is increased while passing through the engine, and the first header tank 10 and the second header tank formed by the combination of the headers 11 and 21 and the tanks 12 and 22. 20; A tube 30 having both ends fixed to the first header tank 10 and the second header tank 20 to form a cooling water flow path; It is formed including a pin 40 interposed between the tube 30. (See Fig. 1)

The radiator is assembled with a condenser on one side and a fan and shroud assembly on the other side to form a cooling module, and the cooling module thus formed is mounted in a carrier opening in front of the vehicle.

However, in a situation where the space inside the engine room cannot be sufficiently secured due to miniaturization and high efficiency, the radiator has a width of the first header tank 10 and the second header tank 20 compared to the width W30 of the tube. (W10, W20) is too large, there is a problem that the width of the entire radiator also has to increase as much as the width (W10, W20) of the first header tank 10 and the second header tank (20).

More specifically, the header tank of the radiator is provided with a gasket along the circumference to secure the inner sealing property as the tank is made of resin and combined with the header, the overall width is to secure the area where the gasket is provided It must be further increased.

In addition, the width of the tube is a factor that determines the flow and amount of the heat exchange medium flowing inside, while securing a sufficient heat dissipation performance is required to reduce the radiator width more.

The present invention has been made to solve the problems described above, the object of the present invention is that both ends of the tube is narrowed in the width direction of the tube and widened in the height direction of the tube is formed in the header tank By reducing the width, the total width of the radiator can be reduced, and the radiator can be miniaturized.

In addition, it is an object of the present invention to provide a radiator that can provide a specific value of the expansion portion to control the internal flow by limiting the numerical value of the expansion portion is easy to manufacture, but the pressure drop of the heat exchange medium does not increase rapidly. .

Radiator 1000 of the present invention is formed by the assembly of the header 101 and the tank 102, the first header tank 110 and the second header tank 120 are provided side by side spaced apart at a predetermined distance, and A radiator comprising a tube 200 having both ends fixed to the first header tank 110 and the second header tank 120 to form a heat exchange medium flow path, and a fin 300 interposed between the tubes 200. In the 1000, the radiator 1000 is inclined at both ends of the tube 200 to be narrowed in the width direction of the tube 200 and inclined to be widened in the height direction of the tube 200. ) And an expansion unit 210 extending in the longitudinal direction at the end of the inclined portion 212 and including an insertion portion 211 inserted into the first header tank 110 and the second header tank 120. And a plurality of tube inserting holes 101-1 corresponding to the inserting portions 211 of the tube 200 are formed in the header 101. The features.

In addition, the tube 200 is characterized in that the circumferential length of the insertion portion 211 of the expansion pipe 210 and the circumferential length of the expansion pipe 210 is not formed.

At this time, the insertion portion 211 of the expansion pipe 210 has a ratio R of the height direction length B of the tube 200 to the width direction length A of the tube 200 is 0.1 to 0.3. Characterized in that formed.

In addition, the inclined portion 212 of the expansion pipe 210 is characterized in that the inclination angle (α) formed with the insertion portion 211 is 6.9 ° to 15 °.

Accordingly, in the radiator of the present invention, both ends of the tube are narrowed in the width direction of the tube and the expansion part is formed to be widened in the height direction of the tube, thereby reducing the width of the header tank, thereby reducing the total width of the radiator. There are possible advantages.

In addition, the radiator of the present invention has the advantage that it is easy to manufacture by limiting the numerical value of the expansion portion, while providing a specific value of the expansion portion that can control the internal flow by preventing the pressure drop of the heat exchange medium to increase rapidly.

1 is a view showing a conventional radiator.
2 is a perspective view of a radiator according to the present invention.
3 is an exploded perspective view of the radiator shown in FIG.
4 is a top plan view of the radiator shown in FIG.
5 is a perspective view of the tube of the radiator according to the present invention.
Figure 6 is a plan view of the tube of the radiator according to the present invention. ((A)-radiator side (up and down direction), (b)-radiator front)
7 is a graph showing the pressure drop according to the ratio of the length in the height direction of the tube to the width in the length direction of the tube of the radiator according to the present invention.
Figure 8 is a graph showing the pressure drop according to the angle formed by the inclined portion and the insertion portion of the radiator according to the present invention.
9 is a view showing a cooling module provided with a radiator according to the present invention.

Hereinafter, the radiator 1000 of the present invention as described above will be described in detail with reference to the accompanying drawings.

The radiator 1000 of the present invention includes a first header tank 110 and a second header tank 120, a tube 200, and a fin 300.

The first header tank 110 and the second header tank 120 are formed by assembling the header 101 and the tank 102, and are provided side by side at a predetermined distance.

The header 101 is formed with a plurality of tube insertion holes 101-1 through which end portions (insertion portions 211) of the tube 200 are inserted, respectively, and a sealing member 103 such as a gasket is provided around the header 101. And a groove 101-2 for coupling with the tube is formed.

The first header tank 110 and the second header tank 120 are formed with an inlet pipe 130 through which a heat exchange medium is introduced and an outlet pipe 140 through which the heat exchange medium is introduced. In some cases, the first header tank 110 is provided. Alternatively, an oil cooler may be provided inside the second header tank 120.

Both ends of the tube 200 are fixed to the first header tank 110 and the second header tank 120 to form a heat exchange medium flow path, and expansion tubes 210 are formed at both ends.

The expansion pipe portion 210 is narrowed in the width direction of the tube 200, the inclined portion 212 is formed to be inclined to widen in the height direction of the tube 200, the longitudinal direction at the end of the inclined portion 212 It is formed to include an insertion portion 211 is extended to the first header tank 110 and the second header tank 120 is inserted.

At this time, the width direction and the height direction of the tube 200 is shown in the drawing, the height direction of the tube 200 is one tube (in the height direction of the entire radiator 1000, which is the stacking direction of the tube 200) 200) means the side.

That is, in the radiator 1000 of the present invention, expansion pipes 210 are formed at both ends of the tube 200, and the insertion part 211 of the expansion pipe 210 is formed of the first header tank 110 and the first header tank 110. Since the width of the two header tanks 120 is formed to be narrow in the width direction of the tube 200, the width of the entire radiator 1000 may also be reduced and miniaturized. (See Figure 4)

In other words, in the radiator 1000 of the present invention, expansion tubes 210 are formed at both ends of the tube 200, so that most of the region of the tube 200 has a sufficient space for the heat exchange medium to flow, The maximum widths (parts formed in the header 101) of the first header tank 110 and the second header tank 120 can be reduced, thereby miniaturizing them.

The tube 200 is an extruded material, the shape forming member corresponding to the shape of the insertion portion 211 is inserted, it can be formed by pressing from the outside, in addition to this can be formed through a variety of methods.

In addition, the circumferential length of the tube 200 of which the expansion pipe 210 is not formed is the same as the circumferential length of the insertion portion 211 of the expansion pipe 210 so as to increase the manufacturability of the entire tube 200. It is desirable to.

The pin 300 is interposed between the tubes 200, and pin gaps 301 are formed at both ends of the tube 200 adjacent to the header 101 tank so that the pin 300 is not formed. .

The pin gap 301 is formed to prevent deformation of the pin 300 during brazing of the header 101, the tube 200, and the pin 300 assembly, and the radiator 1000 of the present invention includes the expansion of the pin gap 301. The formation height of the pin gap 301 may be determined by the formation height of the pipe portion 210.

That is, in the radiator 1000 of the present invention, the tube 200 has no significant change in the depth and the formation height of the pin gap 301, which are inserted into the first header tank 110 and the second header tank 120. The expansion pipe 210 is formed in the first header tank 110 and the second header tank 120 by reducing the width can be miniaturized.

Figure 7 shows the pressure drop according to the ratio (R, B / A) of the height direction length B of the tube 200 to the width direction length (A) of the tube 200 of the radiator 1000 according to the present invention. In the graph, the radiator 1000 of the present invention preferably has a ratio (R) of the height direction length B of the tube 200 to the width direction length A of the tube 200 to be 0.1 to 0.3. Do.

(The ratio R of the height direction length B of the tube 200 to the width direction length A of the tube 200 is formed to be 0.1 to 0.3, which includes 0.1 and 0.3. , Means that the ratio R of the height direction length B of the tube 200 to the width direction length A of the tube 200 is 0.1 or more and 0.3 or less).

As the ratio R of the height direction length B of the tube 200 to the width direction length A of the tube 200 is closer to 1, the pressure drop of the heat exchange medium becomes smaller.

More specifically, the pressure drop amount is 295.9 at the point where the ratio R of the height direction length B of the tube 200 to the width direction length A of the tube 200 is 0.1, and the tube 200 When the ratio (R) of the height direction length (B) of the tube 200 to the width direction length (A) is less than 0.1, the pressure drop is rapidly increased, the width direction length of the tube 200 When the ratio (R) of the height direction length (B) of the tube 200 to (A) is greater than 0.3, when considering the existing tube 200 shape, there is a problem that the production itself is difficult.

Accordingly, since the radiator 1000 of the present invention should be provided with a plurality of tubes 200 to increase the heat exchange area, it is possible to secure a suitable heat exchange area, to facilitate manufacture, and to prevent a sudden increase in the pressure drop. It is preferable that the ratio R of the height direction length B of the said tube 200 with respect to the width direction length A of the tube 200 is 0.1-0.3.

8 is a graph showing the pressure drop amount according to the angle formed by the inclined portion 212 and the insertion portion 211 of the radiator 1000 according to the present invention, the inclined portion 212 of the expansion pipe 210 is It is preferable that the inclination angle (alpha) formed with the insertion part 211 is 6.9 degrees-15 degrees.

(The inclination angle α of the inclined portion 212 includes 6.9 ° and 15 °, and more specifically, the inclination angle α of the inclined portion 212 is 6.9 ° or more and 15 ° or less. do.)

As shown in FIG. 6B, the inclination angle α of the inclined portion 212 is extended from the insertion portion 211 and the inclined portion 212 when the tube 200 is viewed from the side. In the case of the inclination angle α being small, the inclination angle of the inclination portion 212 is increased because the length of the inclination portion 212 is increased to increase the height of the pin gap 301. (α) is preferably formed at 6.9 ° or more.

In addition, when the inclination angle α of the inclined portion 212 is 15 °, the pressure drop amount is 282.8, the pressure of the heat exchange medium when the inclination angle α of the inclined portion 212 exceeds 15 ° Since the fall amount is rapidly increased, it is preferable that the radiator 1000 of the present invention allows the inclination angle α of the inclined portion 212 to be formed to be 6.9 ° or more and 15 ° or less.

The pressure drop of the heat exchanging medium according to the numerical values shown in FIGS. 7 and 8 is a result of the measurement through CFD (Computational Fluid Dynamics) analysis for each selected dimension.

As described above, in the radiator 1000 of the present invention, both ends of the tube 200 are narrowed in the width direction of the tube 200 and the expansion part 210 is formed to be widened in the height direction of the tube 200. By reducing the width of the first header tank 110 and the second header tank 120 to reduce the overall width of the radiator 1000, there is an advantage that can be reduced in size.

In particular, Figure 9 shows a cooling module (C) equipped with a radiator 1000 according to the present invention in (a) and a conventional cooling module (C) in (b).

Radiator 1000 of the present invention can reduce the width of the radiator 1000 as shown in FIG. 9 so that the width of the entire cooling module (C) including the condenser 2000 and the fan and shroud assembly 3000 It can be seen that it can also be reduced.

In addition, the radiator 1000 of the present invention limits the numerical value of the expansion unit 210 so as to easily manufacture the concrete value of the expansion unit 210 that can control the internal flow by preventing the pressure drop of the heat exchange medium from increasing rapidly. There is an advantage that can be provided.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

1000: radiator of the present invention
101: header
101-1: Tube Insertion Hole 101-2: Groove
102 tank
103: sealing member
110: first header tank 120: second header tank
130: inlet pipe 140: outlet pipe
200: tube
210: expansion tube
211: insertion portion 212: inclined portion
A: Tube width direction length of insertion part
B: Length of tube height direction of insertion part
R: Ratio of the length in the height direction of the tube to the width in the width direction of the tube (B / A)
α: inclination angle of the inclined portion
300: pin 301: pin gap
2000: Condenser
3000: Radiator
C: Cooling Module

Claims (4)

The first header tank 110 and the second header tank 120, which are formed by assembling the header 101 and the tank 102, are spaced apart from each other by a predetermined distance, and the first header tank 110. In the radiator (1000) comprising a tube (200) having both ends fixed to the second header tank (120) to form a heat exchange medium flow path, and a fin (300) interposed between the tubes (200),
The radiator 1000 is
At both ends of the tube 200 inclined in the width direction of the tube 200 and inclined to be inclined to widen in the height direction of the tube 200, and to the end of the inclined portion 212 An extension part 210 is formed extending in the longitudinal direction and including an insertion part 211 inserted into the first header tank 110 and the second header tank 120.
A plurality of tube inserting holes 101-1 corresponding to the inserting portion 211 of the tube 200 are formed in the header 101 ,
The insertion part 211 of the expansion pipe 210 has a ratio (R, B / A) of the height direction length B of the tube 200 to the width direction length A of the tube 200. A radiator, characterized in that formed by 0.3.
The method of claim 1,
The tube 200 is a radiator, characterized in that the circumferential length of the insertion portion (211) of the expansion pipe 210 and the circumferential length of the expansion pipe 210 is not formed the same.
delete The method of claim 2,
The inclined portion 212 of the expansion pipe 210 is a radiator, characterized in that the inclination angle (α) formed with the insertion portion 211 is 6.9 ° to 15 °.

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