CN220764026U - Roof ventilation system - Google Patents

Abstract

A roof ventilation system comprises a ventilation plate (11) which is rigidly fixed on an actuating mechanism (13) and a rotary hinge (16) and can tilt relative to a bottom plate (17) and can be driven under the condition that a servo motor (14) outputs torque, and the technical key points are that: the output end of the servo motor (14) is provided with a gear (134); a plurality of ventilation openings (171) are arranged on the bottom plate (17) at intervals along the transverse direction; the actuator (13) includes a ventilation board support (135) for fixing the ventilation board (11), a fixing support (131) for fixing the bottom board (17), a U-shaped rotary arm (132) driven by the servo motor (14) to rotate around the fixing support (131), and a support arm (133) fitted between the U-shaped rotary arm (132) and the ventilation board support (135) with a double pivot shaft. The air ventilator has the advantages of simple and compact structure, high ventilation efficiency and smaller wind noise.

Description

Roof ventilation system

Technical Field

The utility model relates to a ventilation structure of an automobile roof, in particular to a roof ventilation system.

Background

In the existing automobile panoramic sunroof system, an automobile panoramic sunroof is disclosed in the utility model patent with publication number CN 204605475U. In this technical scheme, as described in paragraph 0038 of the specification, if the ventilation function is to be achieved, the driving motor assembly 8 needs to be started to drive the first day window glass 2 to tilt up and then move backwards along the sliding rail 4 for a certain distance, so as to achieve a ventilation function similar to that of a small skylight.

However, it is apparent that the ventilation and ventilation system mainly uses the principle of negative pressure ventilation, and according to aerodynamics, the vehicle is driven by means of air flow rapidly flowing on the roof to form negative pressure in the vehicle, dirty air in the vehicle is drawn out, and fresh air is supplied from the air inlet to perform ventilation and ventilation. Compared with ventilation of a side window, wind noise is smaller.

In order to further reduce wind noise, huang Lei mentions in research on wind vibration problem of automobile sunroof, the sound pressure level (30 dB) is greatly reduced by reducing the opening of the sunroof glass in the windward state, so that the wind vibration problem is solved. In order to meet the ventilation requirement of a large opening of a passenger, the design of the reticular wind shielding strip is adopted under the condition of upwind when the glass is opened, and the effect of overcoming wind vibration is also achieved. However, as shown in tables 1 and 2 herein, the use of weather strips at vehicle speeds of 50km/h and 112km/h still produces a large wind noise in the case of full or half open glass.

It can be seen that the ventilation effect is still limited only by adopting the top opening in the prior art, and the noise reduction effect is not ideal.

Disclosure of Invention

The utility model aims to provide a roof ventilation system which fundamentally solves the problems and has the advantages of simple and compact structure, high ventilation efficiency and smaller wind noise.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the roof ventilation system comprises a ventilation plate which can be driven under the condition that a servo motor outputs torque and is rigidly fixed on an actuating mechanism and a rotary hinge and can tilt up relative to a bottom plate, and the technical key points are as follows:

the output end of the servo motor is provided with a gear;

when the ventilation board is at the lowest tilting position, the ventilation board and the bottom board are sealed by a sealing strip fixed on the bottom board;

a plurality of ventilation openings are arranged on the bottom plate at intervals along the transverse direction;

the actuating mechanism comprises a ventilating plate support for fixing the ventilating plate, a fixed support for fixing the bottom plate, a U-shaped rotating arm driven by a servo motor to rotate around the fixed support, and a supporting arm matched between the U-shaped rotating arm and the ventilating plate support through double pivot shafts;

the support arm is of a strip-shaped structure, and two ends of the support arm are respectively provided with an upper pivot hole for pivotally matching with the ventilation board support and a lower pivot hole pivotally matching with the U-shaped rotating arm;

the U-shaped rotating arm comprises a U-shaped structure, wherein the U-shaped structure comprises a connecting part, a vertical wall part and a driving part, a gear hole matched with a gear is formed in the driving part, a rotating arm pivoting hole coaxial with the gear hole and a supporting arm mounting hole pivoted with a supporting arm are formed in the connecting part, and rotating arm bumps are formed on the side parts of the supporting arm mounting hole;

the fixed support is provided with a rotating arm fixing hole which is coaxially matched with the rotating arm pivoting hole, and the side part of the rotating arm fixing hole is provided with a support bump which is positioned on a plane intersecting with the vertical surface of the fixed support.

The utility model has the beneficial effects that: when the roof glass adopts a fixed panoramic sunroof, the ventilation plate of the roof ventilation system positioned at the front side or the rear side of the roof glass can be opened to realize large-caliber ventilation.

When the roof glass adopts an openable sliding panoramic sunroof (the roof ventilation system is positioned at the rear side of the roof glass), the roof ventilation system and the roof glass are simultaneously opened, and part of air flow flows backwards along a ventilation plate of the roof ventilation system close to the roof glass; part of air flow enters the vehicle from the front opening of the roof glass and then flows out from the ventilation opening of the bottom plate, so that complete ventilation and circulation of air inside the vehicle are realized on the premise of reducing wind resistance and wind noise, and the ventilation efficiency is effectively improved.

Drawings

Fig. 1 is a schematic structural diagram of a use state of one embodiment of the present utility model.

Fig. 2 is a schematic structural diagram of another embodiment of the present utility model in use.

Fig. 3 is a schematic exploded view of the roof ventilation system of the present utility model.

Fig. 4 is a schematic isometric side view of a base plate of the present utility model.

Fig. 4a is a schematic view of a part of the enlarged structure of the portion a in fig. 4.

Fig. 4B is a schematic view of a part of the enlarged structure of the portion B in fig. 4.

Figure 5 is a schematic isometric side view of a ventilation board of the present utility model.

Fig. 5a is a schematic view of a partial enlarged structure of the portion C in fig. 5.

Fig. 6 is a schematic cross-sectional view of the roof ventilation system of the present utility model.

Fig. 7 is a schematic isometric side view of an actuator of the present utility model.

Fig. 7a is an exploded view of fig. 7.

Fig. 8 is a schematic view of two operating states of the present utility model.

Fig. 9 is a schematic diagram of an action principle of one side actuator of the present utility model.

Detailed Description

The following describes the details of the present utility model in detail through specific embodiments with reference to fig. 1 to 9.

Example 1

As shown in fig. 1 and 3, the roof ventilation system 1 is generally provided at the front end of the roof glass 3 adjacent to the front windshield 2. The roof ventilation system 1 specifically includes a floor 17 fixed to a roof frame (not shown), a ventilation board 11 that is tilted with respect to the floor 17, a weather strip 12 that is located between the ventilation board 11 and the floor 17, an actuator 13 for driving the ventilation board 11 to move with respect to the floor 17, and a servo motor 14 that outputs torque to the actuator 13. As shown in fig. 3, 4a and 4b, the bottom plate 17 is provided with more than one ventilation opening 171 arranged along the transverse direction of the vehicle, two sides of the bottom plate 17 are provided with notches for installing the actuating mechanism 13, and two sides of the front end of the bottom plate 17 are provided with caulking grooves for installing the rotary hinge 16. As shown in fig. 6, the seal strip 12 surrounds the ventilation board 11 to form an annular closed space.

As shown in fig. 5 and 5a, the front end of the ventilation board 11 is pivotably mounted on the base plate 17 by a swivel hinge 16, and a weather strip 12 having a bottom fixed to the base plate 17 is provided therebetween. When the vent plate 11 is opened, the vent plate 11 itself is away from the seal strip 12, and the vent plate 11 is pivotally engaged with the rotary shaft 161 by its attachment lugs 111. The rear end of the ventilation board 11 is rigidly fixed to the horizontal mounting surface of the ventilation board support 135 of the actuator 13, and is tilted with respect to the floor 17 by the actuator 13 under the drive of the servo motor 14.

As shown in fig. 7 and 7a, the actuator 13 is preferably a pair of symmetrical structures and positions, and the actuator 13 on the left side of the vehicle is exemplified by the actuator 13 including a fixing bracket 131 for fixing the floor 17, a U-shaped swivel arm 132, a support arm 133, and a ventilation board bracket 135 for fixing the ventilation board 11, which are sequentially provided. Wherein the U-shaped swivel arm 132 is driven by the servo motor 14 by means of outputting a torque thereto. The output shaft of the servo motor 14 is rigidly connected to the gear 134 and the gear 134 may be inserted into the gear hole 1323 of the U-shaped swivel arm 132. The U-shaped rotating arm 132 is formed by bending, so that the plane of the connecting portion 1326 is spaced from the upper half portion of the supporting arm 133, and an installation space is reserved for the first rivet 1361. When in use, the servo motor 14 drives the gear 134 at the output end thereof in a torque output mode, and the gear 134 drives the U-shaped rotating arm 132 to rotate around the rotating shaft of the second rivet 1362, so as to drive the supporting arm 133 and the ventilation board support 135 to lift, and further, the ventilation board 11 is lifted finally. Because the bottom of the connecting line between the upper pivot hole 1332 and the lower pivot hole 1331 of the supporting arm 133 is away from the support bump 1312 when the supporting arm 133 is lifted, the resistance of the ventilation board 11 when the ventilation board is lifted and opened is effectively reduced.

The fixing bracket 131 includes an upper mounting surface 1313 and a vertical surface 1314 where planes intersect, a bracket projection 1312 intersecting both the upper mounting surface 1313 and the vertical surface 1314, and a swivel arm fixing hole 1311 having a shaft hole perpendicular to the vertical surface 1314.

The U-shaped swivel arm 132 includes a U-shaped main body structure composed of a connecting portion 1326, a standing wall portion 1325, and a driving portion 1327. Wherein, the plane of the connecting portion 1326 and the driving portion 1327 is parallel to each other, the connecting portion 1326 is provided with a rotating arm pivot hole 1322 pivoted by a second rivet 1362 and coaxial with the rotating arm fixing hole 1311, the driving portion 1327 is provided with a gear hole 1323 coaxial with the rotating arm pivot hole 1322 and the rotating arm fixing hole 1311, the opposite side of the connecting portion 1326 to the bracket bump 1312 is further provided with a rotating arm bump 1324 located on the plane of the connecting portion 1326, and the connecting portion 1326 is further provided with a supporting arm mounting hole 1321 for connecting the supporting arm 133. The standing wall portion 1325 and the swivel arm projection 1324 serve as a start-stop stroke limiting structure of the fixed bracket 131, so that they are respectively attached to the lower surface and the upper surface of the bracket projection 1312 when the actuator 13 is in the closed and open positions.

The support arm 133 includes a bar-shaped main plate provided with an upper pivot hole 1332 for pivotally coupling the ventilation board support 135 and the first rivet 1361, and a lower pivot hole 1331 for pivotally coupling the support arm mounting hole 1321 of the U-shaped swivel arm 132 and the third rivet 1363.

The ventilation board support 135 includes a flap-shaped body of a folded angle shape, on which a mounting plane is coupled with the upper mounting surface 1313 of the fixing bracket 131, and on a vertical surface of which a support mounting through hole 1351 is provided to be pivotally fitted with the upper pivot hole 1332.

As shown in fig. 8 and 9, when the servo motor 14 drives the U-shaped rotary arm 132 to rotate in the forward direction, the U-shaped rotary arm 132 lifts up the support arm 133, thereby driving the ventilation board 11 fixed on the support arm 133 to tilt up. When the ventilation plate 11 is tilted, the ventilation opening 171 preset on the bottom plate 17 is communicated with the inside and the outside of the vehicle, so that the ventilation function is realized;

similarly, when the servo motor 14 drives the U-shaped rotating arm 132 to rotate reversely, the U-shaped rotating arm 132 withdraws the supporting arm 133 downwards, thereby driving the ventilating plate 11 fixed on the supporting arm 133 to descend and close, keeping sealing with the sealing strip 12, and isolating the ventilating opening 171 on the ventilating plate 11 from the outside of the vehicle.

When the U-shaped rotating arm 132 is positioned at the first working position or the second working position, the connecting lines of the upper pivot hole 1332 and the lower pivot hole 1331 are mutually overlapped to be used as a base line; when the U-shaped swivel arm 132 is rotated from the first operating position to the second operating position, the lower end point of the upper pivot hole 1332 and the lower pivot hole 1331, which are connected, moves away from the base line toward the opposite side of the bracket boss 1312, and then returns to the base line.

Example 2

As shown in fig. 2, the roof ventilation system 1 may be provided at the rear end of the roof glass 3 adjacent to the rear windshield 4. The roof ventilation system 1 has the same structure as that of embodiment 1.

1. Roof ventilation system, 11 ventilation board, 111 connecting ear, 12 sealing strip, 13 actuator, 131 fixing bracket, 1311 swivel arm fixing hole, 1312 bracket bump, 1313 upper mounting surface, 1314 vertical surface, 132U swivel arm, 1321 support arm mounting hole, 1322 swivel arm pivot hole, 1323 gear hole, 1324 swivel arm bump, 1325 vertical wall portion, 1326 connection portion, 1327 drive portion, 133 support arm, 1331 lower pivot hole, 1332 upper pivot hole, 134 gear, 135 ventilation board bracket, 1351 bracket mounting through hole, 1361 first rivet, 1362 second rivet, 1363 third rivet, 14 servo motor, 15 motor bracket, 16 swivel hinge, 161 spindle, 17 bottom plate, 171 ventilation opening;

2. a front windshield;

3. roof glass;

4. a rear windshield.

Claims (2)

1. A roof ventilation system comprising a ventilation plate (11) rigidly fixed to an actuator (13) and a swivel hinge (16) and tilted with respect to a base plate (17) and drivable under the output torque of a servomotor (14), characterized in that:

the output end of the servo motor (14) is provided with a gear (134);

when the ventilation board (11) is at the lowest tilting position, the ventilation board (11) and the bottom board (17) are sealed by a sealing strip (12) fixed on the bottom board (17);

a plurality of ventilation openings (171) are arranged on the bottom plate (17) at intervals along the transverse direction;

the actuating mechanism (13) comprises a ventilation board bracket (135) for fixing the ventilation board (11), a fixing bracket (131) for fixing the bottom board (17), a U-shaped rotating arm (132) driven by a servo motor (14) to rotate around the fixing bracket (131), and a supporting arm (133) matched between the U-shaped rotating arm (132) and the ventilation board bracket (135) through double pivot shafts;

the supporting arm (133) is of a strip-shaped structure, and two ends of the supporting arm are respectively provided with an upper pivoting hole (1332) for pivotally matching with the ventilation board bracket (135) and a lower pivoting hole (1331) for pivotally matching with the U-shaped rotating arm (132);

the U-shaped rotating arm (132) is of a U-shaped structure formed by a connecting part (1326), a vertical wall part (1325) and a driving part (1327), a gear hole (1323) matched with the gear (134) is formed in the driving part (1327), a rotating arm pivoting hole (1322) coaxial with the gear hole (1323) and a supporting arm mounting hole (1321) pivotally matched with the supporting arm (133) are formed in the connecting part (1326), and rotating arm bumps (1324) are formed on the side parts of the supporting arm mounting hole (1321);

the fixed bracket (131) is provided with a rotating arm fixing hole (1311) which is coaxially matched with the rotating arm pivoting hole (1322), and the side part of the rotating arm fixing hole (1311) is provided with a bracket lug (1312) which is positioned on a plane and is intersected with the vertical surface (1314) of the fixed bracket (131).

2. A roof ventilation system according to claim 1, characterized in that: when the U-shaped rotating arm (132) is positioned at the first working position or the second working position, the connecting line of the upper pivot hole (1332) and the lower pivot hole (1331) is mutually overlapped to be used as a base line; when the U-shaped rotary arm (132) rotates from the first working position to the second working position, the lower end point of the connecting line of the upper pivot hole (1332) and the lower pivot hole (1331) moves away from the base line to the deviating side of the support lug (1312) and then returns to the base line.