DE202014101086U1 - Wingless fan - Google Patents

Abstract

Blade-free fan (1) with a base (2) and a nozzle ring (3), the base (2) comprising a base plate (4) and a housing (5), an impeller (14) in the base (2), a motor for driving the impeller and an air guide element (13) are arranged which have an air inlet opening (15) assigned to the impeller (14) and two air outlet openings (16, 17), each of which has an air inlet (19, 20) of the nozzle ring (3) are assigned, characterized in that the nozzle ring (3) is rotatably mounted directly on the housing (5).

Description

The invention relates to a wingless fan having a base and a nozzle ring, wherein the base comprises a base plate and a housing, wherein in the base an impeller, a motor for driving the impeller and an air guide element are arranged, which has an impeller associated with the air inlet opening and two Air outlet openings, which are each associated with an air inlet of the nozzle ring comprises.

Such a wingless fan is for example off EP 2 578 889 A1 known. In this case, a corresponding air flow is generated by movement of the impeller in the base, which is sucked through openings in the housing and is supplied via the air guide element to the nozzle ring. From the nozzle ring, the air then escapes through an annular slot which is formed for example in the region of a front edge of the nozzle ring. The slot can be interrupted by webs, so that it is not compressed even under mechanical loads.

At the EP 2 578 889 A1 known fan, the nozzle ring is rotatably mounted via a pivot member which serves as an air guide at the same time. In this case, the pivoting element is T-shaped and has two air outlet openings, which are associated with corresponding air inlets of the nozzle ring. In an adjustment of the nozzle ring is thus ensured that always the air flow generated by the impeller enters the nozzle ring and can flow through the corresponding nozzle openings.

In this embodiment, the attachment of the nozzle ring relative to the base is relatively unstable, since this is done only indirectly via an additional pivoting element.

The invention is based on the object to improve the stability of a fan, in particular with regard to the connection of the nozzle ring to the base.

According to the invention, this object is achieved in that the nozzle ring is rotatably mounted directly on the housing.

In the solution according to the invention, the connection of the nozzle ring is thus not on the air guide element, but directly on the housing of the base. This results in a very stable attachment. It is exploited that the nozzle ring is rotated about an axis of rotation, which passes centrally through the air inlets of the nozzle ring, or through the air outlet openings of the air guide, so even without direct contact between the air guide and nozzle ring clean air, even with rotation of the nozzle ring relative to the base remains guaranteed.

The nozzle ring is preferably laterally offset relative to the base plate. So he is not centered on the base, but laterally to it. In this case, the top of the housing falls obliquely downwards, so that the nozzle ring is thus mounted below a maximum extent of the housing.

In a preferred embodiment, the air inlets of the nozzle ring are each surrounded by an annular bearing geometry, which cooperate with complementary bearing geometries of the housing. On the housing and the nozzle ring so complementary bearing geometries are formed, which are brought into engagement with each other and thus allow rotation of the nozzle ring and at the same time prevent axial relative movement. The bearing geometries are in particular arranged concentrically around the air inlets of the nozzle ring, so that the air can flow unhindered into the nozzle ring. In this case, the bearing geometries are in particular formed integrally or cohesively with the housing or the nozzle ring. Optionally, additional fasteners may be provided, such as snap rings or the like.

Preferably, the bearing geometry of the nozzle ring has a circumferential annular groove in which engages a radially inwardly projecting flange of the bearing geometry of the housing. This configuration results in a positive connection, which allows rotation of the nozzle ring relative to the housing with simultaneous axial securing position. This results in a relatively dense connection surface, so that only low air losses are to be feared. The flange has in particular an L-shaped cross section and engages in a radially outwardly open annular groove. The annular groove can be formed, for example, by an area with a reduced diameter of the nozzle ring. But it is also conceivable that the annular groove is formed by corresponding peripheral walls which are formed on the outside of the nozzle ring.

Alternatively, it is possible to provide the housing with a corresponding projection with a groove in which an annular flange of the nozzle ring engages.

Preferably, an annular seal is arranged between an inner groove bounding the wall and an annular region of the bearing geometry of the housing. This flow losses are kept small. In addition, can The ring seal already serve to increase a friction between the nozzle ring and the housing so as to hold the nozzle ring in a position once selected.

Preferably, the annular region extends radially to between the air guide element and the nozzle ring. The annular region thus covers the end edge of the nozzle ring in the region of the air inlets. Thus, the area prevents direct contact between the air guide and the nozzle ring. The air guide element and the nozzle ring are therefore mechanically decoupled. In this case, the annular region extends only to the extent that it lies between the end faces of the air guide element and the air inlets of the nozzle ring, without protruding into the openings.

In a preferred embodiment, the annular region on its inner side facing away from the nozzle ring on a particular annular recess for the air guide, which is optionally open radially inwardly. The air guide can be inserted into this recess and thus stabilized on the housing. If the recess is open radially inwardly, it can be formed, so to speak, by an increase in the diameter of the annular region. The production is accordingly easy.

Preferably, the housing relative to the base plate in particular by electric motor pivot. The pivot axis is in particular perpendicular to the base plate and thus perpendicular to the axis of rotation of the nozzle ring. This can be illuminated by a corresponding composite movement almost every area with the emerging from the nozzle ring air jet. In an electromotive control, an automatic pivoting of the housing relative to the base plate can be provided, so that a larger area is outshined. The direction of the led out of the nozzle ring air flow can be adjusted accordingly better.

Preferably, the air guide is pivotally mounted on the base plate, wherein it is guided in the region of its air outlet openings on the housing. The air guide element is therefore fixed at both ends within the base and accordingly remains stable even when pivoting the housing relative to the base. Accordingly, a clean guidance of the air is always guaranteed.

Preferably, the base plate is at least partially radially over the housing over. This achieves increased stability. In particular, the base plate, for example, have an oval cross-section, so that even when pivoting the housing relative to the base plate a stable state is maintained.

In a particularly preferred embodiment, a rotational angle by which the nozzle ring is rotatable relative to the base is limited, wherein the base lies outside the nozzle ring at every possible angle of rotation. The nozzle ring can thus only be rotated by a certain angle range, for example 0 to 270 ° or 0 ° to 180 °, and not completely rotate. Jamming with the base and / or objects in the area of the base is thus prevented. The rotation angle limitation can be achieved for example by non-circularity, by cooperating stops, by locking elements, by a designed only over a partial circumference gear with spring-loaded counterparts and other mechanical forms.

Preferably, in the region of the bearing geometry of the housing, a pressure element is resiliently mounted, which rests radially in the region of the respective bearing geometry on the nozzle ring. The pressure element then provides on the one hand for sufficient friction to hold the nozzle ring in each rotation angle, but can be rotated by manual intervention of the nozzle ring at any time within the released rotation angle range. It is relatively easy to provide appropriate stops in the bearing geometry of the nozzle ring, which ensure by conditioning the pressure element in the circumferential direction that the nozzle ring is rotatable only over a limited range.

Preferably, the housing in the region of the pressure elements each have a bulge. This provides sufficient space for the pressure elements. Also, the housing overall can then remain relatively slim.

In an advantageous embodiment, the region of the bearing geometry of the nozzle ring on which the pressure element comes to rest, for rotational angle limiting a first stop and a second stop. This makes it possible to make a very stable restriction of the rotation angle, with an unintentional adjustment beyond the released rotation angle range is not possible.

The invention will be described in more detail below with reference to a preferred embodiment in conjunction with the drawings. Herein show:

1 a wingless fan in spatial representation,

2 a sectional view of the fan,

3 a detailed view 2 .

4 a sectional view of a slightly modified embodiment and

5 another detail view.

In 1 is a wingless fan 1 presented in a spatial view, which is a base 2 has, at the a nozzle ring 3 is rotatably mounted. The base 2 includes a base plate 4 and a housing 5 , where the case 5 opposite the base plate 4 is pivotable about an axis perpendicular to the base plate 4 stands.

The nozzle ring 3 is opposite the base plate 4 offset laterally and not at the highest point of the housing 5 connected with this, but about halfway up. This is a flat top 6 of the housing 5 flat-sloping down.

To enable rotation about an axis of rotation that is substantially horizontal, is the nozzle ring 3 interrupted at the bottom and has there at its open ends bearing geometries 7 . 8th with which he rotates with corresponding complementary bearing geometries 9 . 10 of the housing is connected. The bearing geometries 7 . 8th of the nozzle ring are made in one piece with these, the bearing geometries 9 . 10 of the housing integral with the housing 5 are formed. The nozzle ring 3 So it's right on the case 5 rotatably mounted.

The nozzle ring 3 has an annular slot on the front 11 on, which is designed as a nozzle for an occurring air flow. The slot 11 is by footbridges 12 interrupted, which provide sufficient mechanical stability. Here are the bars 12 integral with the rest of the nozzle ring 3 formed, which is made for example as an injection molded part made of plastic.

In the base 2 There is a motor, not shown, which drives a likewise not shown impeller. By means of the impeller air is introduced through an opening (not shown) in the housing 5 sucked in and over an air guiding element 13 ( 2 ) in the nozzle ring 3 directed. The opening in the housing 5 is preferably formed lattice-shaped to prevent the penetration of foreign bodies. Optionally, a filter element or the like may be provided following the opening.

As in 2 can be seen, the air guide element has 13 one the impeller 14 assigned air inlet opening 15 as well as two air outlets 16 . 17 on. The air guide 13 is thus T-shaped. It is in the area of the air inlet opening 15 over a pen 18 swiveling with the base plate 4 the base 2 connected. A by rotation of the impeller 14 generated air flow thus occurs via the air inlet opening 15 in the air guide 13 and leaves this via the air outlets 16 . 17 , Because the air outlets 16 . 17 each with an air inlet 19 . 20 of the nozzle ring 3 are assigned, the air flow into the nozzle ring 3 directed. On the nozzle ring 3 the airflow is then over the slot 11 blown out annularly.

The air inlets 19 . 20 of the nozzle ring 3 are concentric of the bearing geometries 7 . 8th Surrounded with the appropriate bearing geometries 9 . 10 of the housing 5 interact.

As in particular from 3 is recognizable, has the bearing geometry 7 . 8th of the nozzle ring 3 a radially outwardly open annular groove 21 in which an L-shaped ring flange of the bearing geometry 9 . 10 of the housing 5 intervenes. Thus, there is an axial position assurance, wherein a rotation of the nozzle ring 3 opposite the housing 5 is possible.

A direct contact between end faces 23 of the nozzle ring 3 in the area of air intakes 19 . 20 with the corresponding front sides 24 of the air guide element 13 is through an annular area 27 in the area of the housing 5 the bearing geometries 9 . 10 prevented. During a movement of the nozzle ring 3 becomes the air guide 13 So it does not affect, but is completely decoupled.

To prevent unwanted air leakage in the area of the bearing geometries 7 . 8th . 9 . 10 To prevent, in each case a ring seal is provided, which in the in 3 shown embodiment on a radial outer side of a wall 27 lies the ring groove 21 bounded axially inward. By this configuration remains up to the air inlet 19 . 20 an annular section 28 of the nozzle ring 3 to which a pressure element 29 is pressed. The pressure element 29 is doing over a spring 30 loaded. It thus ensures frictional grip of the nozzle ring 3 in any desired angular position. Here is the pressure element 29 together with the spring element 30 in a corresponding bulge 31 of the housing 5 accommodated.

To ensure a secure hold of the guide element 13 to ensure this is in the area of its air outlets 16 . 17 in corresponding annular recesses 32 in the case 5 more precisely in the area of the corresponding bearing geometries 9 . 10 introduced. The recesses 32 are doing as an increase in diameter of the annular area 25 surrounded opening formed, which the air passage from the air outlet openings 16 . 17 of the guide element 13 to the air inlets 19 . 20 of nozzle ring 3 allows. Optionally, for further securing position on the air guide 13 a radially outwardly standing, annular stop 33 be provided.

In 4 is one opposite 3 slightly modified design shown. There are additional ring seals 34 . 35 between the wall 27 and the annular area 25 of the housing 5 , About these ring seals 34 . 35 Additionally, a position assurance of the angular position of the nozzle ring 3 opposite the housing 5 by a corresponding frictional connection by the ring seals 34 . 35 are introduced under prestress. Optionally, in this embodiment, the pressure element 29 be waived.

To prevent the nozzle ring 3 around the base 2 is covered, for example, which carries the risk that objects between the nozzle ring 3 and the base 2 jam, is a possible rotation angle of the nozzle ring 3 limited. For example, there are corresponding stops in the section 28 of the nozzle ring 3 provided in the circumferential direction with the pressure element 28 interact and thus limit a possible angle of rotation. Other suitable stops in the area of bearing geometries 7 . 8th . 9 . 10 to limit the angle of rotation are conceivable.

In 5 is the attachment of the pressure element 29 to the section 28 of the nozzle ring 3 shown. For stiffening in the area of the air inlets 19 . 20 has the nozzle ring 3 while corresponding webs 36 . 37 on.

The pressure element 29 has two pin-shaped formations on the underside 38 . 39 on, which is a rotation of the pressure element 29 by positive engagement with corresponding embodiments of the housing 3 prevent.

The invention is not limited to one of the aforementioned embodiments, but can be modified in many ways. So it is possible, for example, in the base 2 in addition to accommodate a heating element to produce heated air, the area of use of the wingless fan 1 to expand. Deviations are also possible with regard to the bearing geometries of the nozzle ring and the housing shown, but a direct connection of the nozzle ring to the housing should be maintained in order to obtain sufficient stability. There are several possibilities for configuring an angle of rotation limitation of the nozzle ring, in particular the provision of stops and / or discontinuities in the area of the bearing geometries.

All of the claims, the description and the drawings resulting features and advantages, including design details, spatial arrangements and method steps may be essential to the invention both in itself and in various combinations.

LIST OF REFERENCE NUMBERS

1

fan

2

Base

3

nozzle ring

4

baseplate

5

casing

6

top

7

bearing geometry

8th

bearing geometry

9

bearing geometry

10

bearing geometry

11

slot

12

Stege

13

air guide

14

impeller

15

Air inlet opening

16

Air outlet opening

17

Air outlet opening

18

pen

19

air intake

20

air intake

21

ring groove

22

annular flange

23

front

24

front

25

annular area

26

ring seal

27

wall

28

section

29

presser

30

spring element

31

bulge

32

recess

33

attack

34

ring seal

35

ring seal

36

stiffening

37

stiffening

38

formation

39

formation

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been 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

• EP 2578889 A1 [0002, 0003]

Claims (13)

Fanless fan ( 1 ) with a base ( 2 ) and a nozzle ring ( 3 ), whereby the basis ( 2 ) a base plate ( 4 ) and a housing ( 5 ), where in the base ( 2 ) an impeller ( 14 ), a motor for driving the impeller and an air guiding element ( 13 ) are arranged, which a the impeller ( 14 ) associated air inlet opening ( 15 ) and two air outlets ( 16 . 17 ), each with an air intake ( 19 . 20 ) of the nozzle ring ( 3 ), characterized in that the nozzle ring ( 3 ) directly on the housing ( 5 ) is rotatably mounted. Fan according to claim 1, characterized in that the air inlets ( 19 . 20 ) of the nozzle ring ( 3 ) each of an annular bearing geometry ( 7 . 8th ) surrounded by complementary bearing geometries ( 9 . 10 ) of the housing ( 5 ) work together. Fan according to claim 2, characterized in that the bearing geometry ( 7 . 8th ) of the nozzle ring ( 3 ) a circumferential annular groove ( 21 ), in which a radially inwardly projecting flange ( 22 ) of the bearing geometry ( 9 . 10 ) of the housing ( 5 ) intervenes. Fan according to claim 3, characterized in that between an annular groove ( 21 ) inside limiting wall ( 27 ) and an annular region ( 25 ) of the housing ( 5 ) a ring seal ( 26 ) is arranged. Fan according to claim 4, characterized in that the annular region ( 25 ) radially to between the air guide element ( 13 ) and the nozzle ring ( 3 ). Fan according to one of claims 4 or 5, characterized in that the annular region ( 25 ) at its the nozzle ring ( 3 ) facing away from the inside a particular annular recess ( 32 ) for the air guiding element ( 13 ), which is optionally open radially inwardly. Fan according to one of the preceding claims, characterized in that the housing ( 5 ) in relation to the base plate ( 4 ) is in particular electromotively pivotable. Fan according to claim 7, characterized in that the air guide element ( 13 ) pivotable on the base plate ( 4 ), wherein it is in the region of its air outlet openings ( 16 . 17 ) on the housing ( 5 ) is guided. Fan according to one of the preceding claims, characterized in that the base plate ( 4 ) at least in sections radially over the housing ( 5 ) survives. Fan according to one of the preceding claims, characterized in that a rotation angle range in which the nozzle ring ( 3 ) compared to the base ( 2 ) is rotatable, is limited, the base ( 2 ) in each rotational angular position outside the nozzle ring ( 3 ) lies. Fan according to claim 10, characterized in that in the region of the bearing geometry ( 9 . 10 ) of the housing ( 5 ) a pressure element ( 29 ) is mounted resiliently that radially in the region of the respective bearing geometry ( 7 . 8th ) rests against the nozzle ring. Fan according to claim 11, characterized in that the housing ( 5 ) in the area of the pressure elements ( 29 ) each have a bulge ( 31 ) having. Fan according to one of claims 11 to 12, characterized in that the area of the bearing geometry ( 7 . 8th ) of the nozzle ring ( 3 ), on which the pressure element ( 29 ) comes to the plant, the rotation angle limiting a first stop and a second stop has.

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