DE102022207513A1 - Air vent for a vehicle - Google Patents

Abstract

The invention relates to an air vent (1) for a vehicle, having a housing (2) which has an air duct (3) with an air inlet section (6) and an air outlet section (7), the air outlet section (7) being connected by an air guide element (12 ) is divided into a first outlet section part (13) and a second outlet section part (14), which are fluidically connected parallel to one another, with an air straightening unit (9) rotatably mounted about a first axis of rotation (10), which is located between the air inlet section (6) and the Air outlet section (7) is arranged and designed to supply an air flow flowing through the air inlet section (6) to the first outlet section part (13) and/or the second outlet section part (14) depending on its rotational position, and with an actuable operating device (63) for rotating the air direction unit (9). It is envisaged that the operating device (63) has an operating unit (28) which is rotatably mounted on or in the air guide element (12) about a second axis of rotation (29) and has a neutral position, the air directing unit (9) being activated by rotating the operating unit (28 ) is rotatable, and wherein the operating unit (28) is assigned at least one return spring (39) for rotating the operating unit (28) into the neutral position.

Description

The invention relates to an air vent for a vehicle, with a housing which has an air duct with an air inlet section and an air outlet section, the air outlet section being divided by an air guide element into a first outlet section part and a second outlet section part, which are fluidically connected in parallel to one another, with a air straightening unit rotatably mounted about a first axis of rotation, which is arranged between the air inlet section and the air outlet section and is designed to supply an air flow flowing through the air inlet section to the first outlet section part and / or the second outlet section part depending on its rotational position, and with an actuable operating device for rotating the Air directing unit.

Air vents of the type mentioned are known from the prior art. For example, the disclosure document discloses DE 10 2016 225 128 A1 an air vent with a housing that has an air duct with an air inlet section and an air outlet section having an air outlet opening. The air outlet section is divided by an air guide element into a first outlet section part and a second outlet section part. The outlet section parts are fluidically connected parallel to one another. An air straightening unit is arranged between the air inlet section and the air outlet section and is rotatably mounted about a first axis of rotation. The air straightening unit is designed to supply an air flow flowing through the air inlet section to the first outlet section part and/or the second outlet section part, depending on its rotational position. There is also an operable operating device for rotating the air straightening unit. Loud DE 10 2016 225 128 A1 The rotation of the air straightening unit can be carried out manually and/or actuator-operated.

The disclosure document JPH08197941A discloses an air vent with a check valve arranged in the air duct. The check valve is gradually adjustable using a ratchet mechanism.

The patent specification DE 102 26 441 B3 discloses an air vent with an actuating element which is equipped with a push-push mechanism.

The invention is based on the object of improving an air vent of the type mentioned in such a way that a space-saving integration of the operating device into the air vent is achieved. In addition, intuitive and comfortable operation of the operating device should be made possible.

The object on which the invention is based is achieved by an air vent with the features of claim 1. According to the invention, it is provided that the operating device has an operating unit which is rotatably mounted on the air guiding element or in the air guiding element about a second axis of rotation and has a neutral position, the air directing unit being rotatable by rotating the operating unit, and the operating unit having at least one return spring for rotating the operating unit the neutral position is assigned. By mounting the control unit on or in the air guide element, the control unit is integrated into the air vent to save space. Preferably, the air guide element has a first air guide wall which forms the first outlet section part and a second air guide wall which also forms the second outlet section part, an interior space being formed between the air guide walls and the operating unit being mounted in the interior space. The second axis of rotation runs through the interior. If the operating unit is stored in the interior, then at least one of the air baffles has an opening or a recess, with the operating unit protruding into the opening or the recess or protruding through the opening or the recess. According to the invention, the air directing unit can be rotated by rotating the operating unit. There is therefore an active connection between the operating unit and the air directing unit, which converts at least certain rotations of the operating unit into rotations of the air directing unit. The operating unit is assigned at least one return spring, which rotates the operating unit back into the neutral position following a rotation out of the neutral position. Because the control unit is always turned back to the neutral position, the control unit can be easily operated even if the control unit is difficult to access. In addition, an air vent with a constant appearance is created, which is particularly visually appealing. Preferably, an end segment of the first outlet section part and an end segment of the second outlet section part are aligned obliquely to one another. With such an alignment of the end segments, an air flow with a different flow direction is provided by the air vent depending on the rotational position of the air straightening unit. The end segments are particularly preferably aligned in such a way that they converge at an acute angle. Preferably, the first axis of rotation and/or the second axis of rotation are aligned perpendicular to the longitudinal central axis of the air duct.

According to a preferred embodiment, it is provided that the operating unit is mechanically operatively connected to the air straightening unit by a ratchet mechanism. The coupling between the air direction unit and the control unit can be safely implemented using a ratchet mechanism. Preferably, the ratchet mechanism is formed by a gear wheel which is non-rotatably connected to the air straightening unit and at least one locking element which interacts with the gear wheel and which can be displaced by rotating the operating unit. According to an alternative embodiment, it is preferably provided that the operating device has an electric motor for rotating the air straightening unit and a control device for controlling the electric motor, wherein the control device is designed to control the electric motor depending on a detected rotation of the operating unit. An advantageous operative connection between the operating unit and the air direction unit can also be realized by such a design of the operating device. A mechanical active connection between the operating unit and the air direction unit is not necessary, so that this embodiment is structurally simple to implement.

According to a preferred embodiment, it is provided that the air directing unit can be rotated out of the neutral position by rotating the operating unit, with a rotation of the operating unit back into the neutral position being independent of a rotation of the air directing unit, or that the air directing unit can be rotated into the by rotating the operating unit Neutral position can be rotated back, with a rotation of the control unit out of the neutral position being independent of a rotation of the air straightening unit. So not every rotation of the control unit is converted into a rotation of the air straightening unit, but only rotations out of the neutral position or rotations back into the neutral position. Such a design of the active connection between the operating unit and the air direction unit can be easily implemented, for example, using a ratchet mechanism.

According to a preferred embodiment, it is provided that the air straightening unit can be rotated by the operating unit either in a first direction of rotation or in a second direction of rotation that is opposite to the first direction of rotation. This results in the advantage that all possible rotational positions of the air direction unit can be adjusted using the control unit. An additional control unit is not necessary for this. Preferably, the operating unit can be rotated in opposite directions of rotation from the neutral position. For example, by rotating the operating unit clockwise, the air straightening unit can be rotated counterclockwise and by rotating the operating unit counterclockwise, the air straightening unit can be rotated clockwise. Alternatively, the air straightening unit can be rotated clockwise by rotating the control unit clockwise and the air straightening unit can be rotated counterclockwise by rotating the control unit counterclockwise.

Preferably, the air straightening unit can be rotated step by step by rotating the operating unit. The air straightening unit is preferably rotatable through a limited rotational position range, the rotational position range having a first end position and a second end position. If the air straightening unit can be rotated step by step by rotating the operating unit, the air straightening unit is only rotated through a section of the limited rotational position range by rotating the operating unit. This means that a particularly precise adjustment of the rotational position of the air straightening unit can be achieved using the operating unit.

According to a preferred embodiment, it is provided that the operating unit protrudes from the air duct through an air outlet opening of the air outlet section. The operating unit is then easily accessible to a user, which makes it easier to operate the operating unit. According to an alternative embodiment, it is provided that a free end of the operating unit to be actuated is arranged in the air duct. The control unit can then be actuated through the air outlet opening. The user must therefore reach into the air duct through the air outlet opening to operate the control unit.

According to a preferred embodiment, it is provided that the operating unit has at least one swan-neck-shaped operating lever. A gooseneck-shaped operating lever has a first section and a second section oriented at an angle to the first section. Due to its angled structure, a gooseneck-shaped operating lever has the advantage that the operating lever can easily be moved out of the air guide element. In particular, the gooseneck-shaped operating lever protrudes from the air guide element through a breakthrough in one of the air guide walls of the air guide element. Preferably, a first operating surface and/or a second operating surface of the operating unit are formed at a free end of the operating lever. The control surfaces are the points of the control unit to which a user applies an actuating force when the control unit is used as intended in order to turn the control unit out of the neutral position.

According to an alternative embodiment, it is preferably provided that a first operating surface of the operating unit is flush with a first air guiding surface of the air guiding element, and/or that a second operating surface of the operating unit is flush with a second air guiding surface of the air guiding element. This design of the control unit has the advantage that an air flow flowing through the air outlet section is only slightly affected by the control element. Rather, the control surfaces essentially form the air control surfaces.

According to a preferred embodiment, it is provided that at least part of the operating unit is mounted displaceably along the second axis of rotation, and that the air vent has a slat arrangement with adjustable air directing slats, which can be adjusted by moving the slidably mounted part of the operating unit. Preferably, a plurality of first air directing slats are arranged in the first outlet section part and a plurality of second air directing slats are arranged in the second outlet section part. Because both the air direction unit and the air direction slats can be adjusted using the control unit, an additional control unit for adjusting the air direction slats can be dispensed with. Preferably, the displaceable part of the operating unit has teeth which interact with the air direction slats to adjust the air direction slats.

According to a preferred embodiment, it is provided that the operating unit has a rotatably mounted base body and an operating element manufactured separately from the base body, the operating element being arranged on the base body in a rotationally fixed manner and being displaceably mounted on the base body. In this way, low-friction mounting of the operating element, i.e. the displaceably mounted part, can be achieved. In particular, the base body is rod-shaped and has a cross-sectional contour that deviates from a circular shape. According to an alternative exemplary embodiment, the operating unit is designed in one piece and, as such, is mounted so that it can move along the second axis of rotation.

According to a preferred embodiment, it is provided that the restoring spring applies a restoring force to the operating element through the base body. As a result, the restoring force is transferred particularly safely to the operating unit, in particular regardless of the sliding position of the operating element on the base body.

The return spring is preferably designed as a flat spring. A flat-form spring is a spring made from cold-rolled spring strip steel. On the one hand, flat springs are available inexpensively. In addition, it can be achieved in a structurally simple manner that the control unit is rotated back into the neutral position regardless of the direction of rotation in which the control unit was rotated from the neutral position. For example, the flat-shaped spring has two sections that are aligned at least substantially parallel to one another and are connected to one another by an elastically deformable bending section. The operating unit or a part of the operating unit is arranged between the bending sections.

According to a preferred embodiment, it is provided that the operating unit has a display means for displaying the rotational position of the air straightening unit. The control unit is always turned back to the neutral position by the return spring. Based on the rotational position of the operating unit, the rotational position of the air straightening unit may not be recognizable. This problem can be solved by the display means. In particular, the display means is designed to visually display the rotational position of the air straightening unit.

The display means particularly preferably has at least one lighting element. The display means is designed to display the rotational position of the air straightening unit by means of the at least one lighting element. This can be realized in different ways. For example, there are several lighting elements, with a different one of the lighting elements or a different group of lighting elements lighting up depending on the rotational position of the air directing unit. Alternatively, the lighting element is designed, for example, to illuminate in a different color depending on the rotational position of the air direction unit.

• 1 einen Luftausströmer,
• 2 eine Bedieneinheit des Luftausströmers,
• 3 eine weitere Darstellung der Bedieneinheit,
• 4 einen Ratschenmechanismus des Luftausströmers,
• 5 eine weitere Bedieneinheit,
• 6 einen weiteren Luftausströmer und
• 7 eine weitere Darstellung des weiteren Luftausströmers.

The invention is explained in more detail below with reference to the drawings. Show this

• 1 an air vent,
• 2 a control unit for the air vent,
• 3 another representation of the control unit,
• 4 a ratchet mechanism of the air vent,
• 5 another control unit,
• 6 another air vent and
• 7 another representation of the additional air vent.

1 shows a sectional view of an air vent 1 for a vehicle. The air vent 1 has a housing 2 with an air duct 3. The air duct 3 is formed by a first housing wall 4 of the housing 2 and a second housing wall 5 of the housing 2 opposite the first housing wall 4. In the present case, in addition to the first housing wall 4 and the second housing wall 5, the air duct 3 is also formed by a third housing wall and a fourth housing wall of the housing 2, the third housing wall being opposite the fourth housing wall. The third housing wall and the fourth housing wall lie outside the cutting plane of the in 1 shown longitudinal section and are therefore not recognizable.

The air duct 3 has an air inlet section 6 and an air outlet section 7. The air inlet section 6 and the air outlet section 7 are connected in series in terms of fluid flow. The air outlet section 7 has an air outlet opening 8. If the air vent 1 is installed in a vehicle as intended, the air outlet opening 8 is assigned to a passenger area of the vehicle. An air flow flowing out of the air vent 1 or the air outlet opening 8 can be supplied to the passenger area accordingly. Between the air inlet section 6 and the air outlet section 7, an air straightening unit 9 is arranged, which is rotatably mounted about a first axis of rotation 10. The first axis of rotation 10 is aligned perpendicular to the longitudinal central axis 11 of the air vent 1.

The air outlet section 7 is divided into a first outlet section part 13 and a second outlet section part 14 by an air guide element 12 arranged fixed to the housing. The first outlet section part 13 and the second outlet section part 14 are fluidically connected in parallel to one another with respect to the air directing unit 9 and the air outlet opening 8. In the present case, both the first outlet section part 13 and the second outlet section part 14 have a curved shape. For this purpose, the housing walls 4 and 5 are each designed to be concave in the area of the air outlet section 7. A first air guide surface 15 of the air guide element 12, which forms the first outlet section part 13, is convex. A second air guide surface 16 of the air guide element 12, which forms the second outlet section part 14, is also convex. Accordingly, the air guide element 12 is designed to be biconvex overall. The first air guide surface 15 is formed by a first air guide wall 25 of the air guide element 12. The second air guide surface 16 is formed by a second air guide wall 26 of the air guide element 12. The air baffles 25 and 26 are spaced apart from one another in such a way that an interior space 27 is formed between the air baffles 25 and 26. The curved course of the outlet section parts 13 and 14 results in an end segment 17 of the first outlet section part 13 and an end segment 18 of the second outlet section part 14 being aligned obliquely to one another. An air flow flowing out of the first outlet section part 13 therefore has a different flow direction than an air flow flowing out of the second outlet section part 14. In the present case, the end segments 17 and 18 converge at an acute angle.

According to the in 1 In the illustrated embodiment, the air inlet section 6 is divided into a first inlet section part 20 and a second inlet section part 21 by a partition wall 19 which is fixed to the housing. The partition 19 is arranged centrally between the first housing wall 4 and the second housing wall 5 in the air inlet section 6. According to a further exemplary embodiment, the partition 19 is dispensed with, so that there is no subdivision of the air inlet section 6.

The air directing unit 9 has a first air directing wall 22 and a second air directing wall 23. The air direction walls 22 and 23 are spaced apart from one another in such a way that an air passage 24 is formed between the air direction walls 22 and 23. In the present case, the air direction walls 22 and 23 are aligned parallel to one another. In the present case, the air straightening unit 9 can be rotated through a limited rotational position range. The limited rotational position range is limited by a first end position and a second end position. 1 shows the air straightening unit 9 in the first end position. In the first end position, the first inlet section part 20 is fluidly connected to the first outlet section part 13 through the air passage 24. The second inlet section part 21 is closed by the first air directing wall 22. The second outlet section part 14 is closed by the second air directing wall 23. In the second end position of the air straightening unit 9, the second inlet section part 21 is fluidly connected to the second outlet section part 14 through the air passage 24. The first inlet section part 20 is closed by the second air directing wall 23. The first outlet section part 13 is closed by the first air directing wall 22. In addition, the air straightening unit 8 has at least one further rotational position located between the end positions, in which both inlet section parts 20 and 21 and both outlet section parts 13 and 14 are each partially released. For example, in a rotational position of the air directing unit 9, the air directing walls 22 and 23 are aligned parallel to the longitudinal central axis 11 of the air vent 1, as in 1 indicated by dashed lines.

The air vent 1 also has an operable operating device 63. The operating device 63 has an operating unit 28 which is located in the interior 27 of the air guiding element 12 a second axis of rotation 29 is rotatably mounted. 1 shows a rotational position of the operating unit 28, which is referred to below as the neutral position. The second axis of rotation 29 runs through the interior 27 and is aligned parallel to the first axis of rotation 10.

The following describes the design of the operating unit 28 with additional reference to 2 and 3 explained in more detail. The operating unit 28 has a base body 30 which is rotatably mounted about the second axis of rotation 29. The base body 30 is rod-shaped. A middle section 31 of the base body 30 has a square cross section. The two end sections 32 and 33 of the base body 30 each have a biconvex cross section with convex rolling surfaces facing away from one another. The operating unit 28 also has an operating element 34 which is arranged on the base body 30 in a rotationally fixed manner. The control element 34 is also mounted on the base body 30 so that it can move along the second axis of rotation 29. The base body 30 is arranged axially fixed in relation to the second axis of rotation 29. The operating element 34 has an operating lever 35. The operating lever 35 protrudes from the air guide element 12 and can be actuated by a user. In the present case, the operating lever 35 is designed in the shape of a gooseneck and protrudes through an opening in the second air baffle 26. At its free end, the operating lever 35 has an operating part 36, which protrudes through the air outlet opening 8 from the air outlet section 7 or the air duct 3. This makes it easier for the user to operate the operating unit 28. The operating unit 28 is based on the in 1 shown neutral position can be rotated in opposite directions of rotation out of the neutral position, as in 2 indicated by the double arrow. In the neutral position, the control panel 36 is arranged centrally in the air outlet opening 8. If the operating unit 28 is to be turned clockwise out of the neutral position, for example, the user applies an actuating force to a first operating surface 37 of the operating part 36. However, if the operating unit 28 is to be turned counterclockwise out of the neutral position, the user applies the actuating force to a second operating surface 64 of the operating part 36 facing away from the first operating surface 37. In the present case, the operating element 34 has two operating levers 35, which together carry the operating part 36. However, only a single operating lever 35 can be present.

At least one return spring 39 is assigned to the operating unit 28. In the present case there are two return springs 39. The return springs 39 are designed to apply a restoring force to the operating unit 28, by means of which the operating unit 28 is rotated into the neutral position. In the present case, the return springs 39 are designed as flat springs 39. The return springs 39 each have a first section 40 and a second section 41 aligned parallel to the first section 40. The sections 40 and 41 of a return spring 39 are each connected to one another by an elastically deformable bending section 38. One of the end sections 32 or 33 is arranged between the sections 40 and 41 of the return springs 39. If the operating unit 28 is rotated clockwise or counterclockwise from the neutral position, the distance between the first sections 40 and the second sections 41 is increased, deforming the bending sections 38. The deformation of the bending sections 38 is accompanied by the generation of the restoring force, through which the operating unit 28 is rotated back into the neutral position.

The operating unit 28 is operatively connected to the air straightening unit 9 in such a way that the air straightening unit 9 can be rotated by rotating the operating unit 28. In the present case, the operating unit 28 is operatively connected to the air straightening unit 9 by a ratchet mechanism 42. However, an electric motor can also be present which rotates the air straightening unit 9 depending on a detected rotation of the operating unit 28. The operating element 28, in this case the base body 30, has a projection 43 which projects radially outwards with respect to the second axis of rotation 29. A coupling rod 44 is rotatably mounted on the projection 43.

An exemplary embodiment of the ratchet mechanism 42 is described below with additional reference 4 explained in more detail, whereby the in 4 The air directing unit 9 shown differs slightly from the one in. with regard to its specific design 1 Air directing unit 9 shown differs. How out 4 As can be seen, the ratchet mechanism 42 has a gear 45 connected in a rotationally fixed manner to the air straightening unit 9. The ratchet mechanism 42 also has a plurality of first locking elements 46 and a plurality of second locking elements 47. The locking elements 46 and 47 are arranged on different sides of the gear 45, at least in the neutral position of the operating unit 28. According to the in 4 In the exemplary embodiment shown, the locking elements 46 and 47 or the ratchet mechanism 42 are designed such that the air straightening unit 9 can be rotated out of the neutral position by rotating the operating unit 28. If the operating unit 28 is rotated counterclockwise from the neutral position, the coupling rod 44 is displaced in a first sliding direction 48. The first locking elements 46 then interact with the gear 45 in such a way that the air straightening unit 9 is rotated clockwise. If the control unit 28 then turned back into the neutral position, the rotation of the operating unit 28 is independent of a rotation of the air straightening unit 9. The coupling rod 44 is slightly raised when rotating back into the neutral position, so that the first locking elements 46 simply slide along the gear 45. The set rotational position of the air straightening unit 9 is therefore retained. If the control unit 28 is turned clockwise out of the neutral position, the coupling rod is moved in a second sliding direction 49. The second locking elements 47 then interact with the gear 45 in such a way that the air straightening unit 9 is rotated counterclockwise. If the operating unit 28 is then rotated back into the neutral position, the rotation of the operating unit 28 is independent of a rotation of the air straightening unit 9. The coupling rod 44 is slightly raised when rotating back into the neutral position, so that the second locking elements 47 only on the gear 45 slide along. According to a further exemplary embodiment, the locking elements 46 and 47 are designed such that the air straightening unit 9 can be rotated back into the neutral position by rotating the operating unit 28, and that a rotation of the operating unit 28 out of the neutral position is independent of a rotation of the air straightening unit 9.

At the in 4 In the exemplary embodiment shown, the air straightening unit 9 can be locked in different rotational positions. For this purpose, a locking ball 50 is present, which locks into a different locking opening 51 of the air straightening unit 9 depending on the rotational position of the air straightening unit 9. If the air straightening unit 9 is rotated by turning the operating unit 28, the locking is released and the locking ball 50 locks into the next locking opening 51 depending on the direction of rotation. The air straightening unit 9 can therefore be rotated step by step by rotating the operating unit 28.

The air vent 1 has a slat arrangement 52. The slat arrangement 52 has a plurality of first air directing slats 53 arranged in the first outlet section part 13 and a plurality of second air directing slats 54 arranged in the second outlet section part 14. The air direction blades 53 and 54 can be adjusted by moving the control element 34 along the second axis of rotation 29. For this purpose, an end of the operating element 34 facing the air straightening unit 9 has teeth 55. The toothing 55 meshes with projections 56 and 57 of the air direction blades 53 and 54 which project into the interior 27.

5 shows a further operating unit 28. Only the operating element 34 of the operating unit 28 is shown. The base body 30 has not been shown. At the in 5 In the control element 34 shown, the control element 34 has a display means 58 for displaying the rotational position of the air straightening unit 9. Because the operating unit 28 is always rotated back to the neutral position, the rotational position of the air straightening unit 9 may not be recognizable based on the rotational position of the operating unit 28. This problem is overcome by the display means 58. At the in 5 In the exemplary embodiment shown, the display means 58 has a lighting element 59. A light guide 60 is formed in the control element 34. A light inlet surface 61 of the light guide 60 faces the lighting element 59. A light outlet surface 62 of the light guide 60 is formed by the first control surface 37. The lighting element 59 is designed to light up in a different color depending on the rotational position of the air straightening unit 9. According to a further exemplary embodiment, the display means 58 has a plurality of lighting elements, with a different one of the lighting elements or a different group of lighting elements lighting up depending on the rotational position of the air directing unit 9.

The 6 and 7 show the air vent 1 according to a further exemplary embodiment, with individual components such as the air direction unit 9 not being shown. The one in the 6 and 7 Air vent 1 shown differs from that in 1 Air vent 1 shown essentially in the design of the control unit 28. In the case in the 6 and 7 The air vent 1 shown closes the first control surface 37 of the control unit 28 flush with the first air guide surface 15. The second control surface 64 is flush with the second air guide surface 16. This is in the 6 and 7 but not noticeable. Also with the one in the 6 and 7 In the illustrated embodiment, the operating unit 28 as a whole or only part of the operating unit 28 is mounted displaceably along the second axis of rotation 29.

Reference symbol list

1

Air vents

2

Housing

3

Air duct

4

First housing wall

5

Second housing wall

6

Air intake section

7

Air outlet section

8th

Air outlet opening

9

Air directing unit

10

First axis of rotation

11

Longitudinal center axis

12

Air guide element

13

First outlet section part

14

Second outlet section part

15

First air control surface

16

Second air control surface

17

End segment

18

End segment

19

Air partition

20

First inlet section part

21

Second inlet section part

22

Air direction wall

23

Air direction wall

24

Air passage

25

First air baffle

26

Second air baffle

27

inner space

28

Control unit

29

Second axis of rotation

30

Basic body

31

Middle section

32

End section

33

End section

34

Control element

35

Control lever

36

Control panel

37

First control surface

38

bending section

39

return spring

40

first section

41

second part

42

Ratchet mechanism

43

head Start

44

Coupling rod

45

gear

46

First locking element

47

Second locking element

48

First sliding direction

49

Second sliding direction

50

locking ball

51

Latching opening

52

Slat arrangement

53

First air direction slat

54

Second air direction slat

55

gearing

56

head Start

57

head Start

58

Display means

59

Lighting element

60

light guide

61

Light inlet area

62

Light outlet surface

63

Operating device

64

Second control surface

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102016225128 A1 [0002]
• JP H08197941 A [0003]
• DE 10226441 B3 [0004]

Claims (14)

Air vent for a vehicle, with a housing (2) which has an air duct (3) with an air inlet section (6) and an air outlet section (7), the air outlet section (7) passing through an air guide element (12) into a first outlet section part (13 ) and a second outlet section part (14), which are fluidically connected parallel to one another, with an air straightening unit (9) rotatably mounted about a first axis of rotation (10), which is arranged between the air inlet section (6) and the air outlet section (7) and to it is designed to supply an air flow flowing through the air inlet section (6) to the first outlet section part (13) and/or the second outlet section part (14) depending on its rotational position, and with an actuable operating device (63) for rotating the air straightening unit (9), thereby characterized in that the operating device (63) has an operating unit (28) which is rotatably mounted on the air guiding element (12) or in the air guiding element (12) about a second axis of rotation (29) and has a neutral position, the air directing unit (9) being rotated by rotating the Operating unit (28) is rotatable, and wherein the operating unit (28) is assigned at least one return spring (39) for rotating the operating unit (28) into the neutral position. Air vent according to the preceding claim, characterized in that the operating unit (28) is mechanically operatively connected to the air directing unit (9) by a ratchet mechanism (42). Air vent according to one of the preceding claims, characterized in that the air directing unit (9) can be rotated out of the neutral position by rotating the operating unit (28), with a rotation of the operating unit (28) back into the neutral position being independent of a rotation of the air directing unit ( 9), or that the air straightening unit (9) can be rotated back into the neutral position by rotating the operating unit (28), wherein a rotation of the operating unit (28) out of the neutral position is independent of a rotation of the air straightening unit (9). Air vent according to one of the preceding claims, characterized in that the air directing unit (9) can be rotated by the operating unit (28) either in a first direction of rotation or in a second direction of rotation opposite to the first direction of rotation. Air vent according to one of the preceding claims, characterized in that the air directing unit (9) can be rotated step by step by rotating the operating unit (28). Air vent according to one of the preceding claims, characterized in that the operating unit (28) protrudes from the air duct (3) through an air outlet opening (8) of the air outlet section (7). Air vent according to one of the preceding claims, characterized in that the operating unit (28) has at least one swan-neck-shaped operating lever (35). Air vents after one of the Claims 1 until 6 , characterized in that a first operating surface (37) of the operating unit (28) is flush with a first air guiding surface (15) of the air guiding element (12), and/or that a second operating surface (64) of the operating unit (28) is flush with a second Air guide surface (16) of the air guide element (12) closes. Air vent according to one of the preceding claims, characterized in that at least part of the operating unit (28) is mounted displaceably along the second axis of rotation (29), and that the air vent (1) has a slat arrangement (52) with adjustable air directing slats (53, 54). which can be adjusted by moving the displaceably mounted part of the control unit (28). Air vents after Claim 9 , characterized in that the operating unit (28) has a rotatably mounted base body (30) and an operating element (34) manufactured separately from the base body (30), the operating element (34) being arranged in a rotationally fixed manner on the base body (30) and on which Base body (30) is slidably mounted. Air vents after Claim 10 , characterized in that the restoring spring (39) applies a restoring force to the base body (30). Air vent according to one of the preceding claims, characterized in that the return spring (39) is designed as a flat spring (39). Air vent according to one of the preceding claims, characterized in that the operating unit (28) has a display means (58) for displaying the rotational position of the air straightening unit (9). Air vents after Claim 13 , characterized in that the display means (58) has at least one lighting element (59).

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