KR20160035825A - Radiator and condenser assembly - Google Patents

Abstract

The present invention relates to a radiator and condenser assembly. When a condenser and a radiator are assembled to each other, a support part and a protruding part are formed in the bottom of a header tank of the radiator without the formation of additional brackets or the like in the header tank of the condenser, and the bottom of a header tank of the condenser is hollowed to allow the bottom end of the header tank of the condenser is open, thereby the protruding part is inserted and coupled to the inner side of the header tank of the condenser. Therefore, the present invention additional process and processing costs for forming a fixing bracket in the header tank of the condenser as the fixing bracket formed in the condenser is not required, and improves the degree of freedom of the design compared with a conventional method for assembling the condenser to the radiator in a vertical downward direction, thereby facilitating the assembly of the radiator and the condenser.

Description

Radiator and condenser assembly < RTI ID = 0.0 >

The present invention relates to a radiator and a condenser assembly, and more particularly, to a radiator and a condenser assembly, in which a header tank of a condenser is assembled without a separate bracket, It is possible to eliminate the fixing bracket formed on the condenser and thus to reduce the production cost and the manufacturing cost of the condenser and to improve the degree of freedom of design compared to the conventional system in which the condenser is assembled to the radiator in the vertical downward direction, will be.

2. Description of the Related Art Generally, in an engine room of a vehicle, various heat exchangers such as a radiator, an intercooler, an evaporator, a condenser, and the like for cooling various components in a vehicle such as an engine or the like, Respectively. Such heat exchangers generally have a heat exchange medium therein, and the heat exchange medium inside the heat exchanger and the air outside the heat exchanger exchange heat with each other, thereby cooling or dissipating heat. Therefore, in order for the various heat exchangers in the vehicle engine room to operate stably, it is natural that outside air should be supplied smoothly into the engine room. Hereinafter, the heat exchangers provided for cooling the vehicle parts or the vehicle interior as described above are collectively referred to as a cooling module.

At this time, the radiator 10 is a device for cooling the heated cooling water while passing through the engine, comprising a pair of first header tanks 11; A first inlet pipe 12 through which cooling water flows and a first outlet pipe 13 through which cooling water flows; A first tube (14) having both ends fixed to the pair of first header tanks (11) to form cooling water flow paths; And a first pin (15) interposed between the first tube (14).

On the other hand, the condenser 20 is included in the refrigerant cycle of the air conditioner, and the refrigerant in a gaseous state of high temperature and high pressure flows into the condenser 20 and is discharged after being condensed into a liquid state while releasing the liquid heat by heat exchange.

The condenser 20 includes a pair of second header tanks 21; A second inlet pipe 22 through which refrigerant flows and a second outlet pipe 23 through which refrigerant flows; A second tube (24) having both ends fixed to the pair of second header tanks (21) to form a refrigerant channel; A second pin (25) interposed between the second tubes (24); And a gas-liquid separator (26) for separating the gaseous refrigerant and the liquid-phase refrigerant.

An embodiment of a structure for assembling the radiator 10 and the condenser 20 integrally is shown in FIGS. 1 and 2. FIG.

As shown in the figure, the radiator and the condenser assembly 1 have the fixing part 16 protruding from the first header tank 11 of the radiator 10, and a separate bracket 27 is provided on the second header tank 11 of the radiator 10, Is formed in the header tank (21), and the bracket (27) is fixed to the fixing portion (16).

In order to increase the clamping force of the radiator and the condenser assembly, it is common that four brackets are provided in each pair of the first header tanks, so that the manufacturing cost of the components and the bracket fixing There is a disadvantage in that the production cost may be increased due to an increase in the additional process and processing cost.

KR 10-2013-0143340 A (2013.12.31)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a radiator and a condenser which are assembled with a radiator, and a bracket or the like is not formed in the header tank of the condenser, The present invention provides a radiator and a condenser assembly capable of removing a fixing bracket formed on a condenser by forming a protrusion, forming a lower portion of the header tank of the condenser and opening the lower end of the condenser, and inserting the protrusion into the header tank of the condenser.

A radiator and a condenser assembly 1000 according to the present invention includes a first header tank 110 and a second header tank 120, A plurality of first tubes 130 to which both ends are fixed to the first and second header tanks 120 and a first fin 140 interposed between the first tubes 130, A radiator 100 including a support part 150 extending in the width direction below the two header tanks 110 and 120 and a protrusion 151 protruding upward from the support part 150; And a second-second header tank 210 and a second-second header tank 220, the second-first header tank 210, and the second-second header tank 220, (200) including a plurality of second tubes (230) having both ends fixed to the first tube (220) to form a refrigerant flow path and a second fin (240) interposed between the second tubes (230); And the protrusions 151 of the radiator 100 are inserted into the open lower ends of the 2-1 header tank 210 and the 2-2 header tank 220 of the condenser 200, .

In addition, a latching protrusion 170 is formed on the first-first header tank 110 and the first-second header tank 120 of the radiator 100, and the second- A fixing bracket 250 is formed on the upper side of the first and second header tanks 210 and 220 and an engaging hole 251 is formed in the fixing bracket 250. The engaging protrusion 170 And the upper side of the radiator 100 and the condenser 200 are fitted to each other.

Further, the latching protrusion 170 is protruded in the width direction.

The first and second header tanks 110 and 120 of the radiator 100 are spaced apart from the upper and lower sides of the locking protrusions 170 to form the second guide portions 182 .

The lower ends of the second and first and second header tanks 210 and 220 of the condenser 200 are supported on the support 150 of the radiator 100 so that the upper end of the protrusion 151 of the radiator 100 is connected to the condenser 200 and the baffle 200a that closes the lower side of the second and first and second header tanks 210 and 220 of the first and second header tanks 200 and 200.

In addition, a cut-out portion 260 is formed at the lower end of the second and first header tanks 2210 and 220 of the condenser 200.

The upper end of the protrusion 151 of the radiator 100 may be inclined or rounded.

The radiator 100 may further include a first guide portion 181 protruding upward from the protrusion 151 in the width direction.

INDUSTRIAL APPLICABILITY The radiator and the condenser assembly of the present invention can eliminate the fixing bracket formed on the condenser, thereby reducing the manufacturing cost of the component, the additional process for forming the fixing bracket, and the processing cost.

In addition, compared with the conventional method of assembling the condenser in the vertical downward direction to the radiator, the degree of freedom of design is improved, which facilitates assembly.

1 is an assembled perspective view of a conventional radiator and a condenser assembly;
2 is a partially exploded perspective view showing a conventional assembling structure of a radiator and a condenser.
3 is an assembled perspective view of a radiator and a condenser assembly of the present invention.
4 is an exploded perspective view showing an assembly structure of a radiator and a condenser according to the present invention.
5 is a partially assembled perspective view illustrating a lower structure of a radiator and a condenser according to the present invention.
6 is a partially assembled perspective view showing an assembly structure on the upper side of the radiator and the condenser according to the present invention.
FIGS. 7 and 8 are side exploded views and assembly views showing a method of mounting and assembling a capacitor in a radiator. FIG.
9 is a front view showing a fixing part according to the present invention.

Hereinafter, a radiator and a condenser assembly according to the present invention will be described in detail with reference to the accompanying drawings.

3 and 4 are exploded perspective views illustrating an assembled perspective view and an assembled structure of the radiator and the condenser according to the present invention, and FIG. 5 is a partially assembled perspective view illustrating the assembled structure of the radiator and the condenser according to the present invention.

As shown, the radiator and condenser assembly 1000 of the present invention includes a first header tank 110, a first header tank 120, a first header tank 110, A plurality of first tubes 130 having both ends fixed to the two header tanks 120 and a first fin 140 interposed between the first tubes 130, A radiator 100 including a support portion 150 extending in a width direction below the support portion 150 and a protrusion 151 protruding upward from the support portion 150; And a second-second header tank 210 and a second-second header tank 220, the second-first header tank 210, and the second-second header tank 220, (200) including a plurality of second tubes (230) having both ends fixed to the first tube (220) to form a refrigerant flow path and a second fin (240) interposed between the second tubes (230); And the protrusions 151 of the radiator 100 are inserted into the open lower ends of the 2-1 header tank 210 and the 2-2 header tank 220 of the condenser 200, .

First, a radiator and a condenser assembly 1000 of the present invention are formed by assembling a radiator 100 and a condenser 200.

The radiator 100 is formed such that the first and second header tanks 110 and 120 are spaced apart from each other by a predetermined distance and the first and second header tanks 110 and 110, Both ends of a plurality of first tubes 130 provided between the first tubes 120 are connected and fixed to form a cooling water flow path and first pins 140 may be interposed between the first tubes 130 . A support portion 150 and a protrusion 151 are formed below the first and second header tanks 110 and 120 so that the support portion 150 is protruded in the width direction from the first and second header tanks 110 and 120. And a protruding portion 151 may protrude from the upper side of the support portion 150. At this time, the first and second header tanks 110 and 120 of the radiator 100 may be formed by a combination of a header and a tank, a header is coupled to the first tube 130, and a tank is disposed outward in the longitudinal direction And the tank may be formed through injection molding so that the tank, the support portion 150, and the protruding portion 151 can be integrally formed.

The condenser 200 is formed such that the 2-1 header tank 210 and the 2-2 header tank 220 are spaced apart from each other by a predetermined distance and the 2-1 header tank 210 and the 2-2 header tank 210, Both ends of a plurality of second tubes 230 provided between the first tubes 220 and the second tubes 230 may be connected and fixed to form a coolant channel and second pins 240 may be interposed between the second tubes 230 . At this time, the 2 < nd > 1 header tank 210 and the 2 < nd > 2 header tank 220 may be formed such that the lower inside is hollow and the lower end is open.

The protrusions 151 of the radiator 100 may be inserted into the open lower ends of the second-1 header tank 210 and the second-second header tank 220 of the condenser 200, 200 can be assembled and coupled to the radiator 100 from the upper side to the lower side.

Accordingly, the radiator and the capacitor assembly according to the present invention can eliminate the fixing bracket formed on the lower side of the condenser, thereby reducing the manufacturing cost of the component, the additional process for forming the fixing bracket, and the processing cost.

At this time, separate engaging portions are formed on the upper side of the 1-1 / 2 header tank 110 of the radiator 100, The bracket may be configured to be inserted and coupled to the engaging portions. That is, a structure in which a conventional radiator and a condenser are coupled can be applied.

The protruding portion 151 of the radiator 100 is formed in the same shape as the hollow lower inside of the second -1 header tank 210 and the second 2 header tank 220 of the condenser 200, So that breakage of a portion where the radiator and the condenser are combined can be prevented.

In addition, a latching protrusion 170 is formed on the first-first header tank 110 and the first-second header tank 120 of the radiator 100, and the second- A fixing bracket 250 is formed on the upper side of the first and second header tanks 210 and 220 and an engaging hole 251 is formed in the fixing bracket 250. The engaging protrusion 170 So that the upper side of the radiator 100 and the condenser 200 can be fitted to each other.

That is, the lower part of the radiator 100 and the condenser 200 can be assembled by inserting the protrusion 151 into the 2-1 header tank 210 and the 2-2 header tank 220, The upper side of the radiator 100 and the condenser 200 can be fitted to each other by the coupling protrusion 170 and the coupling hole 251. More specifically, a latching protrusion 170 protrudes above the first-first header tank 110 and the first-second header tank 120 of the radiator 100, and the second- The fixing bracket 250 is formed on the upper side of the tank 210 and the second-2 header tank 220 so that the fixing bracket 250 is formed with the coupling hole 251 at a position corresponding to the locking projection 170, The coupling protrusion 170 is inserted into the hole 251 and the upper side of the radiator 100 and the condenser 200 are fitted to each other.

In addition, the latching protrusion 170 may protrude in the width direction.

That is, the latching protrusion 170 protrudes in the width direction in the first-first header tank 110 and the first-second header tank 120 of the radiator 100, and the condenser 200 is inserted into the radiator 100, Can be fitted in a direction in which they are stacked. 7 and 8, the condenser 200 is assembled such that the protruding portion 151 is inserted into the header tank at a lower side in an inclined form on one side of the radiator 100, and then the upper side of the inclined condenser 200 The upper side of the condenser 200 can be fitted into the radiator 100 by pushing it toward the radiator 100.

Accordingly, even if there is a structure or parts protruding toward the condenser 200 side in the width direction at the upper end of the radiator 100, the lower side of the condenser 200 can be assembled to the radiator 100 at an oblique angle, Compared to the conventional method in which the condenser 200 is assembled to the radiator 100 in the vertical downward direction.

The first and second header tanks 110 and 120 of the radiator 100 are separated from the upper and lower sides of the latching protrusion 170 to form a second guide portion 182 .

That is, a pair of second guide portions 182 are formed on the upper side and the lower side of the latching protrusion 170 so as to be spaced apart from the latching protrusion 170, and the capacitor 200 is inclined from one surface of the radiator 100 When the upper side of the condenser 200 is fitted to the radiator 100 by pushing the upper side of the tilted capacitor 200 toward the radiator 100 side so that the upper side of the condenser 200 is fitted to the radiator 100, The fixing bracket 250 of the fixing bracket 200 is guided to be inserted into the second guide portion 182 so that the locking protrusion 170 can be accurately inserted into the fitting hole 251 formed in the fixing bracket 250. At this time, the inside of the end portion of the second guide portion 182 may be inclined or rounded to allow the fixing bracket 250 to be inserted more easily.

The lower ends of the second and first and second header tanks 210 and 220 of the condenser 200 are supported on the support 150 of the radiator 100 so that the upper end of the protrusion 151 of the radiator 100 is connected to the condenser 200 and the baffle 200a which closes the lower side of the second and first and second header tanks 210 and 220. [

9, the lower ends of the second and first and second header tanks 210 and 220 of the condenser 200 may be supported on the upper surface of the support 150 of the radiator 100. At this time, A baffle 200a that is disposed apart from the first and second header tanks 210 and 220 of the condenser 200 so as not to transmit loads or vibration directly supported to the baffle 200a, It is possible to prevent the heat exchange medium from leaking inside the header tank.

In addition, cutouts 260 may be formed at the lower ends of the second and first and second header tanks 210 and 220 of the condenser 200, respectively.

That is, since the condenser 200 can be assembled such that the protrusions 151 are inserted into the second and first header tanks 210 and 220 while being inclined with respect to the radiator 100, The incisions 260 may be formed on the lower ends of the radiator 100 and the incisions 260 may be formed on both sides of the radiator 100 in a state where the condenser 200 is inclined.

The circumference of the upper end of the protrusion 151 of the radiator 100 may be inclined or rounded.

When the condenser 200 is assembled to be inserted into the second and first header tanks 210 and 220 with the condenser 200 inclined with respect to the radiator 100, the second and first header tanks 210 and 220 The upper end of the protrusion 151 may be inclined or rounded so that the protrusion 151 can be easily inserted into the lower side of the protrusion 151.

The radiator 100 may be formed with a first guide portion 181 protruding upward from the outside of the protrusion 151 in the width direction.

That is, the first guide portion 181 protruded upward from the outside of the protrusion 151 in the width direction so that the protrusion 151 can be easily inserted into the lower side of the second and first and second header tanks 210 and 220 The first guide portion 181 may have an inclined or rounded upper end on the side of the protruding portion so that the lower portion of the header tank of the condenser 200 can be guided during assembly.

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. It goes without saying that various modifications can be made.

1000: Radiator and capacitor assembly
100: Radiator
110: 1st-1st header tank 120: 1st-2nd header tank
130: first tube 140: first pin
150: Support part 151:
170:
181: first guide portion 182: second guide portion
200: Capacitor 200a: Baffle
210: 2-1 header tank 220: 2-2 header tank
230: second tube 240: second pin
250: Fixing bracket 251: Coupling ball
260: incision

Claims (8)

A plurality of first tubes (110), both ends of which are fixed to the first-first header tank (110) and the first-second header tank (120) A first fin 140 interposed between the first and second tubes 130 and 130, a support 150 extending in the width direction below the first and second header tanks 110 and 120, A radiator (100) including a protrusion (151) protruded upward from the support part (150); And
The second-1 header tank 210 and the second-second header tank 220, which are formed in a manner such that the lower inside is hollow and the lower end is opened, the second-first header tank 210 and the second- A condenser 200 including a plurality of second tubes 230 having both ends fixed to the refrigerant passage 220 to define a refrigerant passage and a second fin 240 interposed between the second tubes 230; And,
And the protrusion 151 of the radiator 100 is inserted into the open lower end of the 2-1 header tank 210 and the 2-2 header tank 220 of the condenser 200. [ And a capacitor assembly.
The method according to claim 1,
A locking protrusion 170 is formed on the top of the first and second header tanks 110 and 120 of the radiator 100,
A fixing bracket 250 is formed on the second-1 header tank 210 and the second-2 header tank 220 of the condenser 200 and a fixing hole 251 is formed in the fixing bracket 250 ,
Wherein a coupling protrusion (170) is inserted into the coupling hole (251) so that the upper side of the radiator (100) and the condenser (200) are fitted to each other.
3. The method of claim 2,
And the latching protrusion (170) protrudes in the width direction.
The method of claim 3,
The second guide portion 182 is formed on the first and second header tanks 110 and 120 of the radiator 100 so as to be separated from the upper and lower sides of the locking protrusion 170 To the radiator and the condenser assembly.
The method according to claim 1,
The lower ends of the second and first and second header tanks 210 and 220 of the condenser 200 are supported on the support 150 of the radiator 100,
The upper end of the protrusion 151 of the radiator 100 is spaced apart from the baffle 200a that closes the lower portion of the second and first header tanks 210 and 220 of the condenser 200. [ .
The method according to claim 1,
Wherein a cut-out portion (260) having both longitudinal sides thereof cut is formed at a lower end of the second and first header tanks (210, 220) of the condenser (200).
The method according to claim 1,
Wherein a periphery of the upper end of the protrusion (151) of the radiator (100) is formed in an inclined or rounded shape.
The method according to claim 1,
Wherein the radiator (100) is formed with a first guide portion (181) protruding upward from the outside of the protrusion (151) in the width direction.

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