WO2015136022A1

WO2015136022A1 - Vacuum cleaner fan

Info

Publication number: WO2015136022A1
Application number: PCT/EP2015/055132
Authority: WO
Inventors: Dieter Manger; Marie-Christin DIETZ
Original assignee: BSH Hausgeräte GmbH
Priority date: 2014-03-12
Filing date: 2015-03-12
Publication date: 2015-09-17
Also published as: EP3116366A1; DE102014204608A1

Abstract

A vacuum cleaner fan comprises a housing, an electric motor having a motor shaft (2) and a fan wheel (1) which is arranged on the motor shaft (2), wherein the motor shaft (2) is mounted by two axially spaced-apart ball bearings such as to be able to rotate relative to the housing, wherein an inner race (6) of a first ball bearing (4) is fixedly connected to the motor shaft (2), and wherein an outer race (7) of the first ball bearing (4) is supported in the axial direction against a bearing surface (18) of a bearing seat (17) via an elastic damping element (23) and is arranged without any contact with the bearing seat (17) in the radial direction. As a result, an improvement can be achieved in terms of the durability of the bearing and/or in terms of the vibration transmission to the housing.

Description

vacuum cleaner fan

description

Field of the invention

The invention relates to a vacuum cleaner fan, which comprises a housing, an electric motor with a motor shaft and a fan wheel, which is arranged on the motor shaft, wherein the motor shaft with two axially spaced ball bearings is rotatably mounted relative to the housing and wherein an inner ring of a first ball bearing fixed connected to the motor shaft.

Background of the invention

In a known vacuum cleaner fan motor shaft is mounted in two axially spaced ball bearings, wherein the two bearings are employed in O arrangement. Both bearings are firmly fixed in their respective bearing seat with the help of a bond. The achieved by the employment bias is additionally increased during operation by the negative pressure generated by the fan, which pulls on the motor shaft. As a result, a backlash and high rigidity can be achieved, since both bearings carry axially.

An important feature of vacuum cleaners is the noise generated during operation, which, among other things, contributes to the structure-borne sound produced by the vacuum cleaner on the blower and transmitted to the housing of the vacuum cleaner via the mechanical coupling of the blower. To reduce structure-borne noise, it is known to store the motor shaft with play.

In the patent US 4,969,797 it is proposed that the shaft of a fan of a blower is mounted at its two ends each with a bearing, wherein the shaft has spirally arranged grooves which suck air through holes in the bearing, so that causes an air bearing in the radial direction becomes. The front end of the shaft is formed with a spherical surface and is in point contact with the center of an end surface of the bearing.

According to WO 2005/029680 A1, a rotor assembly of a motor comprises a rotor arranged on a shaft, the shaft each having a bearing at its two ends. The bearings are mounted with O-rings in a stator assembly, with the O-rings located on the outside of the bearing or a bearing housing rigidly connected to the bearing. This allows the rotor assembly to rotate above its center of mass above a critical speed.

However, the known bearing assemblies are not optimal when used in a vacuum cleaner fan, in particular with regard to the rigidity and durability of the bearing as well as with respect to the vibration transmission to the housing and the structure-borne sound caused thereby.

The problem underlying the invention

It is an object of the invention to provide a generic vacuum cleaner fan, which is improved in particular with regard to the durability of the storage and / or with respect to the vibration transmission to the housing.

Inventive solution

The reference numbers in all claims have no limiting effect, but are only intended to improve their readability.

The solution of the problem is achieved by a vacuum cleaner fan with the features of claim 1.

An inventive vacuum cleaner fan comprises a housing which can be fixedly mounted in a vacuum cleaner housing or, for example, is a part of the vacuum cleaner housing or can be integrated in this. The vacuum cleaner fan serves to generate a suction air flow and generates for this purpose in particular a negative pressure. The housing may include means for guiding the suction air flow. The vacuum cleaner fan further includes an electric motor having a motor shaft carrying a rotor. The vacuum cleaner fan further includes a driven by the electric motor fan, which is in particular fixedly mounted on the motor shaft and which is designed to generate the suction air flow or the negative pressure. The motor shaft is mounted in two ball bearings, which are axially spaced from each other. In particular, a first ball bearing is arranged in an end region of the motor shaft in which the fan wheel is fastened, and a second ball bearing in an end region of the motor shaft opposite this end. The first ball bearing comprises an inner ring and an outer ring, between the rolling elements, in particular balls, are mounted. The ball bearing is preferably designed as a deep groove ball bearing. The inner ring of the first ball bearing is firmly connected to the motor shaft and sits without play on this. The inner ring may for example be firmly connected to the motor shaft by gluing or by a play-free fit.

According to the invention, the outer ring of the first ball bearing is supported on an axial outer surface via an elastic damping element in a bearing seat connected to the housing. In particular, the outer ring is supported in the axial direction against a surface of the bearing seat or held in the axial direction via the elastic damping element. The bearing seat may be formed directly in the housing or formed by a component connected to the housing, such as a guide for guiding the air flow generated by the fan. Furthermore, according to the invention, the outer ring of the first ball bearing is mounted with radial play in the bearing seat, that a radial outer surface of the outer ring of the first ball bearing is arranged without contact with the bearing seat. In the radial direction, i. in a plane which is perpendicular to the longitudinal axis of the motor shaft, the first ball bearing is thus freely movable or elastically held only on the fitting on the axial outer surface of the outer ring elastic damping element.

Characterized in that the outer ring of the first ball bearing is supported on an axial outer surface via an elastic damping element, the coupling of axial vibrations in the bearing seat and thus in the housing can be largely suppressed. Furthermore, the coupling of vibrations in the radial direction by that the radial outer surface does not touch the bearing seat, are largely avoided. Furthermore, as a result of the fact that the outer ring of the first ball bearing is mechanically connected only via the elastic damping element to the bearing seat, rotation of the motor shaft about a center of mass is possible at rotational speeds above a critical speed, even if it is not located on the longitudinal axis of the motor shaft. The center of mass is the center of mass and the center of gravity of the rotor, which includes the motor shaft and the rotor, and the other firmly connected to the motor shaft and co-rotating components, ie in particular the fan and the inner rings of the ball bearings. The critical speed may be, for example, about 20,000 1 / min, with a speed of, for example, up to 60,000 1 / min can be achieved in operation. At operating speed of the engine, a high smoothness of the vacuum cleaner fan can be achieved in this way, whereby the coupling of structure-borne noise is further reduced in the housing.

Preferred embodiment of the invention

Advantageous embodiments and developments, which can be used individually or in combination with each other, are the subject of the dependent claims.

According to a preferred embodiment of the invention, the first ball bearing is arranged close to that end of the motor shaft which carries the fan, and a second ball bearing is arranged on the opposite end of the fan wheel of the motor shaft, wherein an inner ring of the second ball bearing fixed to the motor shaft and a Outer ring of the second ball bearing is firmly connected to the housing. The inner ring may for example be glued to the motor shaft or fixed with a play-free fit on this, and the outer ring may in particular be glued to a further bearing seat of the housing. As a result, the opposite end of the fan wheel of the motor shaft in the axial and radial direction backlash against the housing of the vacuum cleaner fan is stored. Together with the described floating bearing of the first ball bearing, this results in a specific in the axial direction, but in the radial direction in the area of the fan movable mounting. As a result, a sufficiently high rigidity of the bearing can be achieved in a simple manner with a high level of smoothness of the vacuum cleaner fan. Furthermore, it is preferred that the second ball bearing exerts an axially directed force on the motor shaft, through which the outer ring of the first ball bearing is pressed against the elastic damping element and / or this is pressed against the bearing surface of the bearing seat. By such a position, which may be formed in particular as an O-position, the first ball bearing is loaded in the axial direction such that the elastic damping element is held between a bearing surface of the bearing seat and the axial outer surface of the outer ring of the first ball bearing. As a result, the axial fixing of the storage is further improved. Furthermore, this increases the static friction between the outer ring of the first ball bearing or the bearing seat and the elastic damping element, whereby sliding friction, which could occur due to the radial mobility of the outer ring, is reliably avoided. As a result, the durability of the storage can be further increased.

Preferably, the vacuum cleaner fan, in particular the fan and a nozzle of the housing, is designed such that when the fan is driven to generate a negative pressure, this exerts an axial force on the motor shaft through which the outer ring of the first ball bearing to the elastic damping element and this is pressed into the bearing seat or on the bearing surface. As a result, the axial position of the motor shaft is set more precisely and increases the static friction between the elastic damping element and the outer ring of the first ball bearing or the bearing surface, whereby the durability is improved.

In a particularly preferred manner, the employment of the first and the second ball bearing and the negative pressure generated by the fan to increase the pressing force exerted by the outer ring of the first ball bearing on the damping element together. The axial outer side of the outer ring of the first ball bearing is in this case the fan wheel facing side of the outer ring, and the employment of the ball bearing corresponds to an O-employment. As a result, the durability can be further increased.

Preferably, the elastic damping element is designed such that it allows an axial and a radial movement of the outer ring of the first ball bearing relative to the bearing seat. In particular, the elastic damping element is so elastic formed so that even if the outer ring of the first ball bearing bears with its axial outer side fixed to one side of the elastic damping element and the elastic damping element bears with its other side fixed to a bearing surface of the bearing seat, a radial movement of the outer ring relative to the bearing seat can take place , The solid concerns of the damping element on the bearing surface or on the axial outer side of the outer ring can be achieved by cohesive, positive and / or non-positive connection. Thus, in particular, no cohesive connection of the elastic damping element with the bearing seat and the outer ring is required, but it can be held by friction, for example, by the force exerted by the outer ring on the damping element pressing force the damping element. Characterized in that the elastic damping element by deformation allows axial and radial movement of the outer ring relative to the bearing seat, sliding friction between the elastic damping element and the bearing seat and / or the outer ring can be avoided and thereby the durability of the storage can be increased.

According to a preferred embodiment of the invention, the elastic damping element is formed as a disc which is arranged between the axial outside, in particular between an axial end wall of the outer ring or a sealing disc of the first ball bearing, and a bearing surface of the bearing seat. As a result, a support of the outer ring of the first ball bearing with the interposition of the elastic damping element against the bearing seat is made possible in a particularly simple manner. The elastic damping element may be formed as a separate component. In a further advantageous manner, the elastic damping element can be connected to the outer ring, for example, adhered to the axial outer side of the outer ring or on a sealing disc connected thereto. As a result, the assembly of the bearing assembly is facilitated in such a way that the motor shaft can be used with the seated on this first ball bearing and connected to the outer ring of the first ball bearing elastic damping element in the bearing seat.

Furthermore, it is preferred that the elastic damping element is integrally formed on a sealing disc of the first ball bearing. The sealing disc is fixedly connected to the outer ring of the first ball bearing and may consist of an elastic material or be coated by such. Because of that the elastic Damping element is formed integrally with the sealing disc, the manufacture and assembly of the elastic damping element are further simplified.

According to preferred embodiments of the invention, the elastic damping element is flush with the outside of the outer ring of the first ball bearing or projects beyond it. Depending on the design of the bearing seat, a particularly simple assembly can thereby be made possible, wherein at the same time when inserting the first ball bearing in the bearing seat centering, which ensures that the outer side of the outer ring does not touch the bearing seat. A flush with the outer side of the outer ring design of the elastic damping element is preferred when the bearing seat is formed frusto-conical, wherein the outer diameter of the elastic damping element corresponds approximately to the inner diameter of the cone in the area of this final bearing surface. That the elastic damping element projects beyond an axial extension of the outer side of the outer ring is preferred when the bearing seat is cylindrical. In this case, the outer diameter of the elastic damping element substantially corresponds to the inner diameter of the cylinder. In both cases, it can be ensured in a simple manner that the outer ring of the first ball bearing is arranged without contact within the bearing seat.

The elastic damping element is designed in particular as an annular disc with a rectangular, round or semicircular cross-sectional shape. As a result, in a simple manner, a support against a bearing surface of the bearing seat allows a radial mobility of the outer ring of the first ball bearing and possibly a centering in the bearing seat.

In an advantageous manner, the elastic damping element may have a profiled surface, which in particular forms elevations, such as nubs, points or points. Alternatively or additionally, the axial outer surface of the outer ring or the surface of the bearing surface of the bearing seat can be profiled. As a result, the static friction with the bearing surface of the bearing seat and / or the axial outer surface of the outer ring of the first ball bearing increases and a secure frictional engagement can be ensured. In a particularly preferred manner, the elastic damping element on one or both sides of a profiled surface, which corresponds to a profiled surface of the bearing surface of the bearing seat and / or the outer side of the outer ring, so that elevations of one surface in depressions of the other can be used. As a result, the correct position assembly of the elastic damping element or provided with this ball bearing facilitates and centering causes and the frictional engagement can be further improved.

Brief description of the drawings

Further advantageous embodiments will be described in more detail below with reference to three exemplary embodiments illustrated in the drawings, to which the invention is not limited.

They show schematically:

Fig. 1 a and 1 b shows a part of a vacuum cleaner fan according to the prior art in a partially sectioned view, wherein Figure 1 b shows an enlarged detail of Figure 1 a ..;

Fig. 2 shows a first embodiment of the invention in one of the Figure 1 b corresponding view.

3 shows a second embodiment of the invention in a sectional view; and finally

Fig. 4 is a used in an A-bearing according to a third embodiment of the vacuum cleaner fan according to the invention ball bearing in a sectional view. Detailed description based on three embodiments

In the following description of two preferred embodiments of the present invention, like reference characters designate like or similar components. For clarity, not all figures are shown in all figures.

In Fig. 1 a and 1 b is shown in schematic form a part of a vacuum cleaner fan according to a prior art. The fan 1, which is designed to generate a negative pressure, is firmly seated on the motor shaft 2 of a drive motor, which further comprises the seated on the motor shaft 2 rotor 3, which cooperates with a not-shown stator of the motor. The motor shaft 2 is mounted in the region of that end which carries the fan 1 in a first ball bearing 4, which is also referred to as A-bearing. The opposite end of the motor shaft is mounted in a second ball bearing 5, which is referred to as B-bearing. The first ball bearing 4 comprises an inner ring 6, which sits firmly on the motor shaft 2, and an outer ring 7, between which the balls 8 of the ball bearing are arranged in a cage. The outer ring is held without play in the guide 9, which is fixedly connected to the housing, not shown, of the vacuum cleaner fan and which is designed to guide the air flow generated by the fan 1. The second ball bearing 5 has an inner ring 10 and an outer ring 1 1, between which run in a cage, the balls 12 of the ball bearing. The first and the second ball bearings 4, 5 are designed as deep groove ball bearings, wherein the grooves, in which the balls 8, 12 are guided, are not shown for the sake of simplicity. During assembly, the outer ring 1 1 of the second ball bearing 5 is loaded by a conical spring 13 to bias by a position of the second ball bearing 5 against the first ball bearing 4 this form of O-employment against each other, the force lines of action corresponding to the O-employment , In Fig. 1 a are indicated by dash-dotted lines. Thereafter, the outer ring 1 1 of the second ball bearing 5 is fixed in a bearing seat, not shown, of the housing by gluing. The longitudinal axis of the motor shaft 2 is designated by the reference numeral 14.

The area of the first ball bearing 4 (A-bearing) according to the prior art shown in Fig. 1 a is shown enlarged in Fig. 1 b. The inner ring 6 of the first Ball bearing 4 is between a stage 15 of the motor shaft 2 and a flange 16 which carries the fan 1 (see Fig. 1 a), fixed, in particular rotationally fixed and axially and radially clearance with a tight fit on the motor shaft 2 is placed. The nozzle 9 has a bearing seat 17 which is formed by a perpendicular to the longitudinal axis of the motor shaft 2 stationary bearing surface 18 and a truncated cone bearing wall 19. The outer ring 7 of the first ball bearing 4 is attached with its end wall 20, which forms an axial outer side of the outer ring 7, against the bearing surface 18. Between a radial outer side 21 of the outer ring 7 and the frusto-conical bearing wall 19 remains a wedge-shaped tapered gap 22 which is filled to fix the outer ring 7 in the bearing seat 17 of the nozzle 9 with adhesive.

FIG. 2 shows an embodiment of the invention in a representation corresponding to FIG. 1b. In this case, an annular damping element 23 is inserted between the end wall 20 of the outer ring 7 of the first ball bearing 4 and the bearing surface 18 of the bearing seat 17. The end wall 20 is therefore not directly on the bearing surface 18, but only on the damping element 23. Between the radial outer side 21 of the outer ring 7 and the conical bearing wall 19 remains the gap 22, which is not filled with adhesive. Since the damping element keeps the end wall 20 of the outer ring 7 at a distance from the bearing surface 18, the outer ring 7 is held without contact with its radial outer side 21 with the bearing seat 17. The first ball bearing is thus inserted radially loose or with a clearance fit in the bearing seat 17. To facilitate assembly, the gap 22 is wedge-shaped. Due to the O position of the bearings 4, 5, the outer ring 7 is pressed against the damping element 23 and this against the bearing surface 18. In this way, the damping element 23 can be held in its position without gluing. An additional contact force is created by the negative pressure generated by the fan 1 and by the force acting on the motor shaft 2 in the direction indicated by the arrow force is exerted. Incidentally, the embodiment of the invention shown in Fig. 2 is formed as shown in Fig. 1 a.

The interposition of the damping element 23 between the end wall 20 of the outer ring 7 and the bearing surface 18 allows axial mobility of the outer ring 7 and thereby minimizing the axially transmitted vibrations. The missing radial connection of the radial outer side 21 of the outer ring 17 of the first Ball bearing 4 ensures that no vibrations are transmitted radially to the nozzle 9. The elastic bearing also causes a shift of the critical speed to low speeds, for example, about 15 000 1 / min and allows the bearing centering in the conical bearing wall 19 at speeds greater than the critical speed. The bias due to the O-position and the additional force due to the negative pressure generated compress the damping element 23 together. The static friction between the bearing surface 18 and the damping element 23 and / or between the damping element 23 and the end wall 20 of the outer ring 7 of the first ball bearing 4 ensure that the outer ring 7 is stationary within the guide 9 and is not entrained by the rotation of the inner ring 6, which would result in a reduction in durability.

If the speed is far above the critical speed, the motor shaft will center itself, i. the center of gravity approaches the axis of rotation; the motor shaft stabilizes and the vacuum cleaner fan runs quieter. This effect is independent of the exact installation position of the shaft and of other forces acting on the shaft. The vibrations transmitted radially from the first ball bearing to the housing can thereby be reduced at operating speed to, for example, 1/5 in comparison to the state of the art shown in FIGS. 1 a and 1 b, almost regardless of which unbalance the motor shaft 2 with the co-rotating components Has. Accordingly, a significant reduction of the sound power level can be achieved.

A sectional view of a second embodiment of the invention is shown in FIG. 3 again. As can be seen in FIG. 3, the damping element 23 largely covers the bearing surface 18, the outer edge of the damping element 23 projecting slightly beyond the outer contour of the outer ring 7. The damping element 23 has been connected prior to assembly with the outer ring 7 and the sealing washer 24 of the first ball bearing 4, for example, or sprayed on. During assembly, the outer ring 7 is inserted with the damping element 23 in the bearing seat 17. The bearing wall 19 is funnel-shaped in a front part to facilitate the insertion of the first ball bearing 4 with the damping element 23 mounted thereon in the bearing seat 17. In the rear part of the bearing wall 19 is cylindrical. The projection of the damping element 23 via the radial outer side 21 of the outer ring 7 ensures that between the radial outer side 21 and the Storage wall 19 remains a gap and the outer ring 7 radially does not touch the bearing wall 19. Incidentally, the second embodiment is formed as the first.

The damping element is designed in the described embodiments as a silicone rubber ring with an outer diameter of about 22 mm, an inner diameter of about 16 mm and a thickness of about 0.5 mm.

In Fig. 4 is an embodiment of the first ball bearing 4 with a one piece with a sealing washer 24 executed damping element 23 is shown enlarged in section. The sealing washer 24 seals the cage 25, in which the balls 8 run, from the outside and is fixed to the outer ring 7, in particular rotationally fixed, connected. On the inner ring 6, the sealing washer is slidingly mounted in sealing grooves 26. The damping element 23 is integrally connected to the sealing washer 24 via a connecting portion 27. The damping element terminates flush with the outer side 21 of the outer ring 7 or ends slightly within an extension of the outer side 21 and is designed as a ring with a thickness of about 0.3 mm and an outer diameter of about 22 mm, facing away from the outer ring 7 , substantially flat surface has an inner diameter of about 19 mm. Incidentally, a vacuum cleaner fan according to this embodiment of the invention is constructed like the first embodiment described above.

The features disclosed in the foregoing description, the claims and the drawings may be of importance both individually and in any combination for the realization of the invention in its various forms.

LIST OF REFERENCE NUMBERS

1 fan wheel

2 motor shaft

3 runners

4 First ball bearing

5 second ball bearing

6 inner ring

7 outer ring

8 ball

9 distributor

10 inner ring

1 1 outer ring

12 ball

13 cone spring

14 longitudinal axis

15 level

16 flange

17 bearing seat

18 storage area

19 storage wall

20 front wall

21 outside

22 gap

23 damping element

24 sealing washer

25 cage

26 sealing groove

27 connection area

Claims

1 . Vacuum cleaner fan, comprising a housing, an electric motor with a motor shaft (2) and a fan wheel (1) which is arranged on the motor shaft (2), wherein the motor shaft (2) is rotatably mounted with two axially spaced ball bearings relative to the housing and wherein an inner ring (6) of a first ball bearing (4) fixedly connected to the motor shaft (2), characterized in that an outer ring (7) of the first ball bearing (4) in the axial direction via an elastic damping element (23) against a Bearing surface (18) of a bearing seat (17) is supported and arranged in the radial direction without contact with the bearing seat (17).

2. Vacuum cleaner fan according to claim 1, characterized in that the first ball bearing (4) in a fan wheel (1) carrying end portion of the motor shaft (2) is arranged and a second ball bearing (5) at an opposite end of the motor shaft (2) is, wherein an inner ring (10) of the second ball bearing (5) fixed to the motor shaft (2) and an outer ring (1 1) of the second ball bearing (5) is fixedly connected to the housing.

3. Vacuum cleaner fan according to claim 2, characterized in that the second ball bearing (5) such a directed axial force on the motor shaft (2) exerts that the outer ring (7) of the first ball bearing (4) to the elastic damping element (23) and / or the elastic damping element (23) is pressed against the bearing surface (18) of the bearing seat (17).

4. Vacuum cleaner fan according to one of the preceding claims, characterized in that the fan wheel (1) and the housing are designed such that when the fan wheel (1) is driven, this exerts such a directed axial force on the motor shaft (2), in that the outer ring (7) of the first ball bearing (4) is pressed against the elastic damping element (23) and / or the elastic damping element (23) against the bearing surface (18) of the bearing seat (17).

5. Vacuum cleaner fan according to one of the preceding claims, characterized in that the elastic damping element (23) is designed such that an axial and a radial movement of the outer ring (7) relative to the bearing seat (17) is made possible.

6. Vacuum cleaner fan according to one of the preceding claims, characterized in that the elastic damping element (23) as a between an axial end wall (20) of the outer ring (7) of the first ball bearing (4) and the bearing surface (18) of the bearing seat (17). arranged disc is formed.

7. Vacuum cleaner fan according to one of the preceding claims, characterized in that the elastic damping element (23) with the outer ring (7) of the first ball bearing (4) is connected.

8. Vacuum cleaner fan according to claim 7, characterized in that the elastic damping element (23) is integrally formed on a sealing washer (24) of the first ball bearing (4).

9. Vacuum cleaner fan according to one of the preceding claims, characterized in that the elastic damping element (23) is flush with a radial outer side (21) of the outer ring (7) of the first ball bearing (4) or projects beyond this.

10. Vacuum cleaner fan according to one of the preceding claims, characterized in that the elastic damping element (23) is designed as an annular disc with a rectangular, round or semi-circular cross-sectional shape.

1 1. Vacuum cleaner fan according to one of the preceding claims, characterized in that the elastic damping element (23) is profiled on its surface facing the bearing surface (18) and / or the outer ring (7) of the first ball bearing (4).

12. Vacuum cleaner fan according to one of the preceding claims, characterized in that the bearing surface (18) and / or an axial end wall (20) of the outer ring (7) of the first ball bearing (4) is profiled.