KR102635820B1 - Active Air Flap - Google Patents

Abstract

The present invention relates to an active air flap for controlling the cooling wind flowing into a vehicle heat exchanger. More specifically, the present invention relates to an active air flap that guides the cooling wind due to interference with the loader for mounting the front end module on the vehicle. The present invention relates to an active air flap in which a part of a guide has been removed, and an active air flap that prevents cooling air leakage generated through the air guide deletion part.

Description

Active Air Flap {Active Air Flap}

The present invention relates to an active air flap for controlling the cooling wind flowing into a vehicle heat exchanger. More specifically, the present invention relates to an active air flap that guides the cooling wind due to interference with the loader for mounting the front end module on the vehicle. The present invention relates to an active air flap in which a part of a guide has been removed, and an active air flap that prevents cooling air leakage generated through the air guide deletion part.

Generally, in the engine room of a vehicle, there are not only driving parts such as the engine, but also various heat exchangers such as radiators, intercoolers, evaporators, and condensers to cool each part of the vehicle such as the engine or to control the air temperature inside the vehicle. are provided. Such heat exchangers generally have a heat exchange medium distributed inside them, and cooling or heat dissipation is achieved by heat exchange between the heat exchange medium inside the heat exchanger and the air outside the heat exchanger. Therefore, it is natural that in order for the various heat exchangers in the vehicle engine room to operate stably, external air must be smoothly supplied to the engine room. Hereinafter, as described above, heat exchangers provided for cooling vehicle parts or vehicle interior are collectively referred to as heat exchangers.

Meanwhile, in recent automobile development, there has been a growing tendency to reduce the number of parts and processes to improve productivity. One of the ways to improve productivity is to assemble multiple parts individually to form an assembly and assemble them on an assembly line. In other words, modularization technology is being proposed, a representative example of which is a front-end module modularized by assembling a bumper including a heat exchanger, headlamp, and bumper beam stay.

Figure 1 shows an exploded perspective view of a typical front end module for a vehicle, and Figure 2 shows an exploded perspective view of a conventional active air flap.

1 is a diagram showing a front end module, where the front end module is centered around a carrier 10 consisting of a front panel 11 and support panels 12 extending from both ends of the front panel at a predetermined angle. Thus, a heat exchanger 30 is mounted behind the front panel 11 of the carrier 10, and a headlamp ( (not shown) is mounted, and a bumper 20 is mounted on the front of the carrier 10 to make it modular.

The heat exchanger 30 may be modularized into a cooling module including the heat exchanger 30 and placed behind the front panel 11, and may be formed in various ways depending on the design, as shown in the drawing. It is shown briefly above.

In the front end module shown in FIG. 1, in order to smoothly distribute external air to the heat exchanger 30 provided inside the carrier 10, an opening for air inflow is generally provided on the bumper 20 side. 21) is formed.

The opening 21 may simply have holes as shown, and a structure in the form of a net or grill may be installed on the opening 21 to prevent foreign substances from entering the opening 21. It may also be in the form of more provisions.

When the vehicle is driven, external air quickly flows into the opening 21, and thus smooth heat exchange can be achieved in the heat exchanger 30 provided inside the carrier 10.

However, when the vehicle is initially started and until the engine temperature rises within a certain range, the inflow of external air through the opening 21 does not help improve aerodynamic power and fuel efficiency.

Additionally, when the vehicle travels at high speed, the flow of air flowing into the opening 21 also becomes very high-speed, and thus air resistance becomes very large. As the vehicle traveling speed increases, air resistance increases, so the vehicle engine must generate more energy, resulting in poor fuel efficiency.

The conventional opening 21 was a fixed structure in the form of a hole, so it was fundamentally impossible to control the flow rate of air flowing in while driving the vehicle, and therefore, as described above, during initial startup and high speed. There was a problem that the problem of reduced fuel efficiency due to increased resistance of air flowing into the engine room during driving could not be solved.

In order to solve the above problem, as shown in FIG. 2, an active air flap is installed between the opening 21 and the heat exchanger 30 to control the amount of air flowing in from the opening 21. ) (40) may be provided.

The AAF (40) helps improve aerodynamics and fuel efficiency by sealing the opening (21) during initial startup and until the engine temperature rises within a certain range. When the engine temperature exceeds a certain temperature, it opens the opening (21) to close the engine. It helps with cooling and plays a role in reducing air resistance by appropriately adjusting the air flow rate when the vehicle is driving at high speed.

The AAF (40) is located at the rear end of the opening 21 and includes an air guide 41 that guides the air flowing in through the opening 21, and an air guide 41 located at the rear end of the air guide 41. It includes a body 43 provided with a door 42 that opens or closes, and an actuator 44 provided on the body 43 to drive the door 42.

Figure 3 shows a side schematic diagram of the front end module (FEM) loaded into the loader (L), and Figure 4 shows a plan schematic diagram of the front end module (FEM) loaded into the loader (L).

Meanwhile, as shown in FIGS. 3 and 4, the front end module (FEM) is loaded through a loader (L) and mounted in the front of the engine room of the vehicle. The loader (L) includes a first loader (L1) that supports the upper and lower sides of the front end module (FEM), and a second loader that supports the lower end of the bumper beam (B) located in front of the front end module (FEM). It consists of (L2).

At this time, in the case of the AAF (40) provided on the lower side of the bumper beam (B), interference occurs with the upper part of the air guide (41) when the second loader (L2) loads the bumper beam (B). To solve this problem, There is an interference avoidance portion 41a formed by cutting a portion of the air guide 41. If the interference avoidance part (41a) exists on the air guide (41) of the AAF (40), the cooling wind flowing into the air guide (41) is not completely transmitted to the rear heat exchanger and leaks into the interference avoidance part (41a). Therefore, a problem occurs in which the heat exchange performance of the heat exchanger deteriorates.

The present invention was devised to solve the above problems, and the purpose of the present invention is to provide a leak prevention member that can be assembled to the interference avoidance part formed on the air guide of the AAF after the front end module is assembled to the vehicle. The aim is to provide an active air flap that allows post-assembly of the leak prevention member to the interference avoidance area.

In addition, the leak prevention member provides an active air flap that is coupled to the air guide of the active air flap through a snap-in or button type coupling.

The active air flap of the present invention includes a carrier 10, a bumper 20 mounted on the front of the carrier 10 and having an opening 21 to allow air to flow to the rear of the carrier 10, and the carrier 10. In the active air flap 100 (Active Air Flap) mounted at the rear of (10) and provided on the front end module including the heat exchanger 30 in which the core is formed, the active air flap 100 is , an air guide 110 located at the rear end of the opening 21 and guiding the air flowing in through the opening 21; A door 120 provided on the air guide 110 and opening or closing the air guide 110; And an actuator 140 provided in the air guide 110 to drive the door 120, wherein the loader supports the front end module when the front end module is mounted on a vehicle on the air guide 110. An interference avoidance portion 111 is formed that is recessed from the front to the rear of the vehicle to prevent interference, and the active air flap 100 is a leak coupled to the interference avoidance portion 111 after the front end module is mounted on the vehicle. It further includes a prevention member 500.

In addition, the active air flap is provided on the lower side of the bumper beam provided between the carrier and the bumper, and the interference avoidance portion 111 is configured to prevent interference with the loader supporting the bumper beam. It is characterized in that it is formed in the central part of the upper surface of 110).

In addition, the length of the interference avoidance unit 111 in the vehicle width direction is characterized in that it is formed to be longer than the width of the loader.

At this time, the leak prevention member 500 includes a flat plate portion 510 coupled to the interference avoidance portion 111 in a plate shape; A reinforcement portion 520 formed along the periphery of the flat plate portion 510 and extending outward from the upper surface of the flat plate portion; And it includes coupling parts 550 and 560 that protrude rearward from the rear side of the vehicle of the flat part 510 for fastening and coupling with the air guide 110.

In addition, the reinforcement portion 520 is characterized in that it is formed on a portion of the circumference of the flat portion 510 that corresponds to the coupling portion to the interference avoidance portion 111.

In addition, the air guide 110 includes an air guide reinforcement part 115 extending upward around the interference avoidance part 111 to correspond to the reinforcement part 520.

In addition, the leak prevention member 500 is slide-coupled to the air guide 110 along the front and rear direction of the vehicle.

In addition, the leak prevention member 500 and the interference avoidance portion 111 are characterized in that rail coupling portions 590 and 190 are formed along the front and rear direction of the vehicle on both sides in the vehicle width direction.

In addition, the leak prevention member 500 protrudes toward the rear of the vehicle and includes a hook-shaped first guide coupling portion 550, and the air guide 110 includes the first guide coupling portion 550. ) The leak prevention member 500, including a first coupling portion 150 made of a ring-shaped coupling portion 151, is snap-fitted to the air guide 110 along the front and rear direction of the vehicle. Do it as

In addition, a coupling protrusion 551 is formed on the first guide coupling portion 550, and the coupling protrusion 551 is the first coupling protrusion when the leak prevention member 500 is coupled to the air guide 110. It contacts the front side edge of the vehicle to limit the coupling position of the leak prevention member 500.

In addition, the first coupling portion 150 is formed at the rear of the vehicle of the interference avoidance portion 111, and the leak prevention member 500 and the interference avoidance portion 111 are located on both sides in the vehicle width direction in the front and rear direction of the vehicle. It is characterized in that rail coupling portions 590 and 190 are formed along.

In addition, the leak prevention member 500 protrudes toward the rear of the vehicle and includes a hook-shaped second guide coupling portion 560, and the air guide 110 includes the second guide coupling portion 560. ) The leak prevention member 500, including a second coupling portion 160 consisting of a coupling groove 161 recessed from the front to the rear of the vehicle so that the They are fit together, and the second coupling portion 160 is formed on the rear side of the vehicle, on both sides in the vehicle width direction, or on both the rear side of the vehicle and on both sides of the vehicle width direction, of the interference avoidance portion 111.

In addition, the second guide coupling portion 560, when the leak prevention member 500 is coupled to the air guide 110, the end abuts against the rear side end of the vehicle of the coupling groove 161, thereby forming the leak prevention member 500. ) limits the binding site.

In addition, the leak prevention member 500 includes a third guide coupling portion 570 made of a button-type hook 571 formed on the lower surface, and the air guide 110 is coupled to the third guide. The leak prevention member 500, including a third coupling portion 170 made of a button hole 171 so that the portion 570 is inserted, is fitted and coupled to the air guide 110 along the top and bottom of the vehicle, and the third coupling portion 170 is inserted into the air guide 110. The coupling portion 170 is formed on the rear side of the vehicle, on both sides in the vehicle width direction, or on both the rear side of the vehicle and on both sides in the vehicle width direction, of the interference avoidance portion 111.

The active air flap of the present invention with the above configuration prevents leakage of cooling air that may occur through the interference avoidance portion formed to prevent interference with the loader, thereby improving the heat exchange performance of the heat exchanger located at the rear of the active air flap. It has the effect of preventing deterioration.

In addition, the leak prevention member is coupled to the air guide through a snap-in or button type coupling, thereby simplifying the assembly process, thereby reducing production costs and time, thereby improving productivity.

Figure 1 is an FEM exploded perspective view
Figure 2 is an exploded perspective view of a conventional AAF
Figure 3 is a side schematic diagram of the front-end module loaded in the loader.
Figure 4 is a plan schematic diagram of the front-end module loaded in the loader.
Figure 5 is a perspective view before assembly of the leak prevention member of the AAF according to an embodiment of the present invention.
Figure 6 is a perspective view after assembling the leak prevention member of the AAF according to an embodiment of the present invention.
Figure 7 is a perspective view of a leak prevention member of AAF according to an embodiment of the present invention.
Figure 8 is a cross-sectional view in the vehicle width direction of the guide coupling part of the AAF according to an embodiment of the present invention.
9 is a cross-sectional view in the vehicle width direction of the guide coupling part of the AAF according to another embodiment of the present invention.
10 is a cross-sectional view of the guide coupling part of the AAF in the front and rear directions of the vehicle according to an embodiment of the present invention.
11 is a cross-sectional view of the guide coupling portion of the AAF according to another embodiment of the present invention.
Figure 12 is a perspective view before assembly of the leak prevention member of the AAF according to another embodiment of the present invention.
13 is a cross-sectional view of the guide coupling portion of the AAF according to another embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings. The embodiments introduced below are provided as examples to ensure that the idea of the present invention can be sufficiently conveyed to those skilled in the art. The present invention is not limited to the embodiments described below and may be embodied in other forms.

Referring to Figure 1, the present invention includes a carrier 10 consisting of a front panel 11 and a support panel 12 extending from both ends of the front panel 11, and is mounted on the front of the carrier 10 and carries the carrier ( A front end including a bumper 20 with an opening 21 formed to allow air to flow to the rear of the carrier 10, and a heat exchanger 30 mounted on the rear of the front panel 11 of the carrier 10 and forming a core. It relates to an active air flap (40) provided in the module to open or close the opening (21), and is installed in the bumper (20) to allow the heat exchanger (30) to be air-cooled to the rear of the carrier (10). An opening 21 through which air circulates may be formed. The opening 21 is formed in the bumper 20 to allow air to flow in and allow the heat exchanger 30 to operate smoothly. However, when the vehicle is driven at high speed, the amount of air flowing in also increases more than necessary, and the flow of air causes resistance. This causes a decrease in vehicle fuel efficiency. The opening 21 is divided into an upper grill formed on the upper side of the bumper and a lower grill formed on the lower side of the bumper, and the AAF 40 can be installed in both the upper and lower openings.

Meanwhile, the AAF of the present invention is provided in a vehicle with an opening formed only at the bottom of the bumper 20, such as an electric vehicle, and prevents leakage of cooling air flowing into the AAF without causing interference with the loader for mounting the front end module. It has its characteristics. Hereinafter, the AAF of the present invention having the above features will be described in detail with reference to the drawings.

Figure 5 shows an exploded perspective view of the AAF (100) according to an embodiment of the present invention, and Figure 6 shows an overall perspective view of the AAF (100) according to an embodiment of the present invention.

As shown, the AAF 100 of the present invention is configured to open or close the opening of the bumper as needed, and includes an air guide 110 located at the rear end of the opening to guide air flowing in through the opening; , a door 120 installed in the body 130 coupled to the rear end of the air guide 110 to open or close the air guide 110 according to rotation, and a door 120 provided on the body 130 and rotated to open or close the door 120. It includes an actuator 140 that rotates. The air guide 110 and the body 130 may be formed separately and assembled, or may be formed integrally as shown in the drawing.

The air guide 110 may be formed in a box or cylindrical shape with open front and rear sides. The air guide 110 is located at the rear of the opening and serves to guide air flowing in along the opening. At this time, an interference avoidance portion 111 may be formed on the air guide 110 to avoid interference with a loader (refer to prior art) for supporting the lower end of the bumper beam (refer to prior art) when the FEM is mounted on a vehicle. The interference avoidance portion 111 is formed on the upper side of the air guide 110. The interference avoidance portion 111 may be recessed from the front side end of the air guide 110 to the rear side of the vehicle. The interference avoidance portion 111 may be formed not only on the upper side of the air guide 110 but also at any location that may be subject to interference by the loader.

The body 130 is formed at the rear end of the air guide 110. An actuator 140 is installed in the center of the body 130, and doors 120 are installed on both sides of the actuator 140 on the body 130. As another example, the actuator 140 may be installed on one side or the other side of the body 130 in the vehicle width direction, and the door 120 may be installed on only one side or the other side. An open or closed insertion portion to which a shaft is coupled so that the door 120 can rotate around the shaft may be formed on one side and the other side of the body 130 where the door 120 is installed.

The door 120 may have the configuration of a typical door including blades formed in the left and right longitudinal directions and shafts protruding outward at both ends of the blades. The door 120 is located on the body 130 to open or close the air flowing in through the opening. The door 120 is opened when the blade is parallel to the air flow direction by rotating the blade with the shaft as the rotation axis, It closes when it becomes vertical.

The actuator 140 may be provided at the center of the body 130. The actuator 140 is connected to the door 120 and rotates the door 120 according to instructions from the control unit. That is, rotation of the actuator 140 in one direction can rotate the door 120 to open the air guide 110, and rotation of the actuator 140 in the other direction can rotate the door 120 to close the air guide 110. The actuator 140 may be configured as a commonly used motor.

At this time, the AAF (100) according to an embodiment of the present invention has the following characteristic configuration to prevent the cooling wind flowing in through the air guide (110) from leaking into the interference avoidance portion (111) formed in the air guide (110). has The AAF 100 includes a leak prevention member 500 that is assembled to the interference avoidance portion 111 after the FEM is mounted on the vehicle and the loader is separated from the bumper beam.

The leak prevention member 500 has a shape corresponding to the interference avoidance portion 111, and is provided with a first guide coupling portion 550 to be coupled to the air guide 110. In addition, when the leak prevention member 500 is coupled, a first coupling portion 150 corresponding to the first guide coupling portion 550 is formed on the air guide 110. In this embodiment, a method in which the leak prevention member 500 is slide coupled along the front and rear direction of the vehicle was applied. Hereinafter, the detailed configuration of the leak prevention member 500 as described above will be described in detail with reference to the drawings.

Figure 7 shows an overall perspective view of the leak prevention member 500 according to an embodiment of the present invention, and Figure 8 shows a cross-sectional view of the guide coupling part of the AAF in the vehicle width direction according to an embodiment of the present invention. As shown, the leak prevention member 500 includes a flat plate portion 510, a reinforcing portion 520, and a coupling portion 550. As shown, the flat portion 510 is formed in a plate shape corresponding to the interference avoidance portion 111, and a reinforcing portion 520 may be formed along the circumference of the flat portion 510. The reinforcing part 520 may have a predetermined thickness and extend outward from the upper surface of the flat part 510 in the plane direction of the leak prevention member 500. The reinforcement portion 520 is formed to correspond to a portion of the circumference of the flat portion 510 that is coupled to the interference avoidance portion 111. The rigidity of the coupling part of the leak prevention member 500 is reinforced through the configuration of the reinforcement part 520, and the reinforcement part 520 is configured to surround the interference avoidance part 111 of the air guide 110 from the top to the bottom. It is configured to prevent air from leaking from the coupling portion when the leak prevention member 500 and the interference avoidance portion 111 are coupled.

The first coupling portion 150 may be formed on the rear side of the vehicle of the interference avoidance portion 111. In this case, in order to prevent clearance from occurring in the vertical direction when the leak prevention member 500 is assembled to the interference avoidance part 111, the side and interference avoidance part of the leak prevention member 500 ( Rail coupling portions 190 and 590 may be formed on the side of 111).

Figure 9 shows a cross-sectional view of the guide coupling part of the AAF in the vehicle width direction according to another embodiment of the present invention. As shown, an air guide reinforcement portion 115 may be formed around the interference avoidance portion 111 of the air guide 110 to correspond to the reinforcement portion 520 described above. The air guide reinforcement portion 115 extends upward from the perimeter of the interference avoidance portion 111, and has the effect of reinforcing the rigidity of the joint around the interference avoidance portion 111 through the configuration of the air guide reinforcement portion 115. There is.

Figure 10 shows a cross-sectional view of the guide coupling portion (GC) of the AAF 100 in the front and rear direction of the vehicle according to an embodiment of the present invention.

As shown, in the leak prevention member 500, a first guide coupling portion 550 is formed to protrude toward the rear side of the vehicle of the leak prevention member 500, and the first guide coupling portion 550 may be formed in a hook shape. In addition, the first coupling portion 150 formed on the air guide 110 has a ring-shaped coupling portion 151 formed so that the hook-shaped first guide coupling portion 550 is fitted. Therefore, the leak prevention member 500 can be coupled to the interference avoidance portion 111 of the air guide 110 in a snap fit manner. In addition, when the leak prevention member 500 is coupled, a coupling protrusion 551 is formed on the first guide coupling part 550, and the coupling protrusion 551 is in contact with the vehicle front side end of the first coupling part 150. The coupling range of the leak prevention member 500 can be limited.

Figure 11 shows a cross-sectional view of the guide coupling portion (GC) of the AAF 100 in the front and rear direction of the vehicle according to another embodiment of the present invention.

As shown, in the leak prevention member 500, a second guide coupling portion 560 is formed to protrude toward the rear side of the vehicle of the leak prevention member 500, and the second guide coupling portion 560 may be formed in a hook shape. In addition, the second coupling portion 160 formed on the air guide 110 has a coupling groove 161 recessed from the front to the rear of the vehicle so that the hook-shaped second guide coupling portion 560 is fitted. Therefore, the leak prevention member 500 can be coupled to the interference avoidance portion 111 of the air guide 110 in a snap fit manner. In addition, when the leak prevention member 500 is coupled, the end of the second guide coupling portion 550 is configured to contact the side end of the coupling groove 161, thereby limiting the coupling range of the leak prevention member 500.

Figure 12 shows an exploded perspective view of the AAF 100 according to another embodiment of the present invention, and Figure 13 shows a cross-sectional view of the guide coupling portion GC of the AAF 100 according to another embodiment of the present invention. It is shown.

AAF (100) according to another embodiment of the present invention has the following characteristic configuration to prevent cooling wind flowing in through the air guide (110) from leaking into the interference avoidance portion (111) formed in the air guide (110). has The AAF 100 includes a leak prevention member 500 that is assembled to the interference avoidance portion 111 after the FEM is mounted on the vehicle and the loader is separated from the bumper beam. The leak prevention member 500 has a shape corresponding to the interference avoidance portion 111, and is provided with a third guide coupling portion 570 to be coupled to the air guide 110. In addition, when the leak prevention member 500 is coupled, a third coupling portion 170 corresponding to the third guide coupling portion 570 is formed on the air guide 110. In this embodiment, a method of fitting the leak prevention member 500 by applying force downward from the top of the vehicle was applied. Accordingly, the third coupling portion 170 may be formed on both sides of the interference avoidance portion 111 in the vehicle rear side and the vehicle width direction, respectively.

Referring to Figure 13, in the leak prevention member 500, a third guide coupling portion 570 is formed on the lower surface of the leak prevention member 500, and the third guide coupling portion 570 is a button-type hook 571. ) can be achieved including. Therefore, the leak prevention member 500 may be extended to have a larger area on both sides of the vehicle rear side and vehicle width direction than the interference avoidance portion 111, or may be extended only at the area where the third guide coupling portion 570 is formed. there is.

In addition, the third coupling portion 170 formed on the air guide 110 includes a button hole 171 so that the button-type hook 571 is inserted. Therefore, the leak prevention member 500 can be coupled to the interference avoidance portion 111 of the air guide 110 using a button hole coupling method.

The technical idea of the present invention should not be interpreted as limited to the above-described embodiments. Not only is the scope of application diverse, but various modifications can be made at the level of those skilled in the art without departing from the gist of the present invention as claimed in the claims. Therefore, such improvements and changes fall within the scope of protection of the present invention as long as they are obvious to those skilled in the art.

100: Active air flap
110: Air guide 111: Interference avoidance section
150, 160, 170: coupling part 190, 590: rail coupling part
120: door
130: body
140: actuator
500: Leak prevention member
550, 560, 570: Guide coupling part

Claims (14)

Active air provided in a front end module including a carrier, a bumper mounted on the front of the carrier and having an opening to allow air to flow to the rear of the carrier, and a heat exchanger mounted on the rear of the carrier and forming a core. In the flap (Active Air Flap),
The active air flap is,
an air guide located at the rear end of the opening to guide air flowing in through the opening;
a door provided on the air guide and opening or closing the air guide; and
Includes an actuator provided in the air guide to drive the door,
An interference avoidance portion recessed from the front of the vehicle to the rear of the vehicle is formed on the air guide to prevent interference with the loader supporting the front-end module when the front-end module is mounted on the vehicle,
The active air flap further includes a leak prevention member coupled to the interference avoidance unit after the front end module is mounted on the vehicle.
According to clause 1,
The active air flap is,
It is provided on the lower side of the bumper beam provided between the carrier and the bumper,
The interference avoidance part is an active air flap, characterized in that it is formed in the center of the upper surface of the air guide to prevent interference with the loader supporting the bumper beam.
According to clause 1,
The length of the interference avoidance section in the vehicle width direction is,
An active air flap, characterized in that it is formed longer than the width of the loader.
According to clause 1,
The leak prevention member is,
A flat plate portion coupled to the interference avoidance portion in a plate shape;
A reinforcement portion formed along the periphery of the flat plate portion and extending outward from the upper surface of the flat portion; and
An active air flap including a coupling portion protruding rearward from the rear side of the vehicle of the flat portion for fastening the coupling with the air guide.
According to clause 4,
An active air flap, characterized in that the reinforcement portion is formed on a portion of the circumference of the flat portion that corresponds to the coupling portion of the interference avoidance portion.
According to clause 5,
The air guide is,
An active air flap comprising an air guide reinforcement portion extending upward around the interference avoidance portion to correspond to the reinforcement portion.
According to clause 1,
The leak prevention member is,
An active air flap, characterized in that it is slidably coupled to the air guide along the front and rear direction of the vehicle.
According to clause 7,
In the leak prevention member and interference avoidance part,
An active air flap, characterized in that rail joints are formed along the front and rear direction of the vehicle on both sides of the vehicle width direction.
According to clause 7,
The leak prevention member is,
It protrudes toward the rear of the vehicle and includes a hook-shaped first guide coupling portion,
The air guide is,
Including a first coupling portion made of a ring-shaped coupling portion so that the first guide coupling portion is inserted.
The leak prevention member is an active air flap, characterized in that it is snap-fitted to the air guide along the front and rear direction of the vehicle.
According to clause 9,
A coupling jaw is formed on the first guide coupling portion,
The coupling jaw is an active air flap that abuts the front side end of the vehicle of the first coupling portion when the leak prevention member is coupled to the air guide to limit the coupling position of the leak prevention member.
According to clause 9,
The first coupling portion,
Formed at the rear of the vehicle of the interference avoidance unit,
In the leak prevention member and interference avoidance part,
An active air flap, characterized in that rail joints are formed along the front and rear direction of the vehicle on both sides of the vehicle width direction.
According to clause 7,
The leak prevention member is,
It protrudes toward the rear of the vehicle and includes a hook-shaped second guide coupling portion,
The air guide is,
Including a second coupling part consisting of a coupling groove recessed from the front to the rear of the vehicle so that the second guide coupling part is inserted.
The leak prevention member is snap-fitted to the air guide along the front and rear direction of the vehicle,
The second coupling portion,
An active air flap formed on the rear side of the vehicle or both sides in the vehicle width direction of the interference avoidance unit, or on both the rear side of the vehicle and the vehicle width direction.
According to clause 12,
The second guide coupling part,
An active air flap that, when the leak prevention member is coupled to the air guide, the end contacts the rear side end of the vehicle in the coupling groove to limit the coupling position of the leak prevention member.
According to clause 1,
The leak prevention member is,
It includes a third guide coupling portion made of a button-type hook formed on the lower surface,
The air guide is,
Including a third coupling portion made of a button hole so that the third guide coupling portion is inserted.
The leak prevention member is fitted into the air guide along the top and bottom of the vehicle,
The third coupling part,
An active air flap formed on the rear side of the vehicle or both sides in the vehicle width direction of the interference avoidance unit, or on both the rear side of the vehicle and the vehicle width direction.

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