ES2460393A2 - Oscillation damper for a household appliance with rotating drum, and household appliance comprising the damper - Google Patents

Abstract

The invention relates to an oscillation damper 1 for a household appliance 9, in particular a washing machine 9 or dryer 9, with a fixed support 2 mountable on a lower part of the housing 10 of the household appliance 9 in which is housed an oscillating group comprising a tub 15, a drum 13, and a motor 21, a pivot shaft 3 mounted on a support 2 and in which is mounted a radial friction element 4, a swiveling lever 5 associated with the radial damper 4, and articulable 5a to a support element 24 simultaneously articulated to a lower part of the tub 15, and an elastic element with at least a helical spring 6, 6' with windings arranged around the pivot shaft 3 and connected to the swiveling lever 5 and the fixed support 2, opposing a torsional force to the rotation of the swiveling lever 5, and designed such that the torsional force corresponds to a proportional part of the load of the oscillating group transmitted by the support element 24.

Description

The present invention falls within the technical field of vibration damping devices, particularly radial dampers, and is especially useful in household appliances such as washing machines and dryers.

Washing machines and dryers with a washing drum rotatably housed in a washing tank usually have a vibration damping device, which joins the washing tank with the housing. By means of the vibration damping device, the vibrations and the noises caused by the rotating movement of the drum are damped.

The vibrations are transmitted to the damping elements to avoid that the movement of the oscillating group (set: washing tank, drum and motor) is transmitted directly to the frame of the washing machine, and causes vibrations and noise in it.

Virtually all washing machines on the market have the same arrangement of their balancing and hanging systems of their oscillating group, that is, 2 or 3 springs that must withstand a load of, for example, 42 to 48 kg (weight of the oscillating groups ). Being hung on top of the frame logically transmit vibrations and reactions to the furniture that become vibrations and noise. In the lower part the usual thing is to stop the movements with 2 or 3 shock absorbers.

To absorb these vibrations, linear damping systems are known which comprise cylinder piston damping devices, such as the free-travel damper described in application EP-1754908-A, which have a small path without frictional force ( 5mm to 8mm). These dampers act essentially in the stages in which the machine's motor is accelerating or decelerating the rotation speed of the drum, that is, when the oscillating movements are longer, because the inertia is greater, so that it is exceeded the amplitude of the free travel, without friction, of the damper, and this exerts its braking action. When the load present in the washing drum is stabilized, and higher speed regimes are reached, the oscillating movements have less amplitude and the piston displacement is reduced, so that it moves in the area of the free path without exerting force of friction With this it is possible to eliminate or reduce the force to be transmitted to the frame, the vibrations and consequently the noise, because friction force is not exerted since the tank does not move hardly, and the small movement it performs is not limited by the shock absorber to not transmit forces to the frame. However, these free-running linear vibration dampers are relatively complex and expensive.

Radial dampers are known as described, for example, in the application WO 2011/070092-A1, whereby a necessary frictional force is achieved radially, whereby friction is caused by the rotation of an axis which in turn is operated by a rigid arm that comes from the tank. It is an example of a crank rod and the friction is done on the shaft and radially, so it does not directly affect the crossbar that supports the legs and, therefore, does not transmit the flexions.

In known damping systems, a substantial part of the weight of the oscillating group is being supported by the springs from which the oscillating group hangs, which causes that, despite the presence of the dampers that support the lower part of the oscillating group , a part of the oscillations of the oscillating group, is transmitted to the housing of the domestic appliance through these springs thus causing vibrations and noise.

The object of the present invention is to overcome the drawbacks of the state of the art detailed above, by means of an oscillation damper for a household appliance, particularly for a washing machine or dryer, and a domestic appliance comprising at least one oscillation damper of this kind.

The oscillation damper according to the present invention comprises a fixed support mountably fixed in a lower part of the housing of the domestic appliance in which an oscillating group comprising a tank is housed.

in which a drum rotates) around a pivot axis, a pivot axis mounted on the support, a radial rotation damper mounted on the pivot axis, as well as a tilting lever integral to the radial damper, with a free end articulable to a support element articulated in turn to a lower part of the tank that receives a load from the oscillating group, and is characterized in that

it comprises an elastic shock absorber comprising at least one metallic helical spring with turns arranged around the pivot axis and with a first end connected to the rocker lever and a second end connected to the fixed support, so as to oppose a torsional force to the rotation of the rocker lever;

The elastic shock absorber is designed so that the torsional force that opposes the rotation of the rocker lever corresponds to a proportional part of the load of the oscillating group transmitted by the support element to which the rocker lever is articulated.

On the other hand, the domestic appliance, particularly the washer or dryer machine, according to the present invention comprises a housing that houses the oscillating group comprising the washing tank in which the washing drum driven by the motor rotates The tank is connected with the housing superiorly by means of at least one pair of support springs and inferiorly through at least two support elements connected to an oscillation damping system. The support element is articulated to the housing with interleaving of at least one joint comprising a radial vibration damper. This domestic appliance is characterized in that at least one of the rocker levers is articulated to an oscillation damper that has at least the characteristics described above, although it may also have one or more of the oscillation damper characteristics that will be described below.

The oscillation damper is designed to oppose a torsional force to the load of the oscillating group received by the articulated support element to the rocker lever. The load of the oscillating group is based on the weight of the assembly formed by the washing tank, the drum and the motor that form the oscillating group plus the weight of the maximum volume of the washing water present in the washing tank and the maximum weight possible of the clothes present in the drum which, during the rotation of the drum during the washing and spinning process, exert forces that lead to the mentioned oscillations whose transmission to the housing of the lifting machine is mitigated by using the oscillation damper of the present invention. In a washing machine with a washing capacity of 7 kg of clothes, this oscillating group usually has a weight of 42 to 48 kg and the maximum total weight of water and clothes is usually about 15 kg.

In a preferred embodiment of the oscillation damper, the fixed support comprises a first end housing and a second end housing on which the pivot axis is mounted, and the radial rotation damper is mounted on an intermediate part of the pivot axis. According to this embodiment, the elastic damper comprises a first coil spring with turns arranged around the pivot axis between the first housing and the radial damper and a second coil spring with turns arranged around the pivot axis between the second housing and the radial damper.

The tilting lever may comprise two hinged lugs to the support element, in which case the first helical spring is connected by its first end to one of the lugs and by its second end to the first end housing, and the second helical spring is connected by its first end to the other lug and from its second end to the second end housing.

Preferably, the first end of each helical spring is connected to the rocker lever close to the pivot axis. This first end of each helical spring can be connected to the rocker lever allowing a limited rotation of the rocker lever without opposing the torsional force, which prevents those of oscillations that are below a certain threshold value, which do not result in vibrations important in the housing of the domestic appliance, make the oscillation damper go into action unnecessarily, which reduces the wear of the oscillation damper.

To achieve this effect, the rocker lever can be provided with a guide groove in which the first end of the coil spring slides during the limited rotation of the rocker lever, and which extends perpendicularly with respect to the pivot axis. This guide groove comprises an upper guide, a lower guide and a support wall that is disposed between first ends of the upper guide and the lower guide, and on which the first end of the helical spring is supported when the rocker lever is subjected to the load of the oscillating group received by the support element to which the rocker lever is articulated. The guide groove may be provided with a retaining wall disposed between second ends of the upper and lower guides opposite the support wall. Alternatively, the guide groove may be an inlet that, instead of the retaining wall, comprises an access opening between the second ends of the upper and lower guides opposite the support wall. When the rocker lever comprises the two lugs, each of them comprises such a guide groove.

In one embodiment of the invention, the radial rotation damper comprises an outer bushing integral with the tilting lever arranged with rotation capacity with respect to the pivot axis, and also comprises internal friction means that radially embrace the pivoting axis exerting a force of friction to dampen the rotating movement between the pivot shaft and the outer sleeve. The purpose of the radial rotation damper is to reduce a certain type of oscillations, the shortest and most frequent ones, which are basically produced with the machine stabilized at constant speed, so that friction and the transmission of vibrations to the carcass housing can be reduced domestic appliance, in the phase of greatest number of turns or oscillations.

This radial rotation damper may comprise an inner bushing housed in the outer bushing with turning capacity. The inner bushing comprises an outer wall facing an inner wall of the outer bushing and an axial inner passage in which the internal friction means are radially arranged exerting a frictional force at least on the inner bushing. The rotation between the inner bushing and the outer bushing is limited by a turning delimiter system comprising at least one axial channel located between the inner bushing and the outer bushing and at least one turning boundary element located in the axial carcass, which It has a cross-section in the form of a circular crown segment delimited between two radial end stop surfaces. Each turning delimiter element is selected from emerging projections of the inner wall of the outer bushing, emerging projections of the outer wall of the inner bushing, sliding locking elements, and combinations thereof. Each projecting element is movable in the corresponding axial channel so that, by rotating the outer bushing and the inner bushing, each projecting element has a free travel in the axial channel limited by said abutment surfaces. The free travel of the rotation between the outer bushing and the inner bushing can, for example, correspond to an arc of 1 to 4o. Through this free travel, it is achieved that only the oscillations produced by oscillations transmitted by the support element that have an intensity greater than a predetermined threshold value, corresponding to an intensity below which said oscillations result in a transmission of vibrations of an acceptable level to the housing of the domestic appliance, cause the sliding locking elements to move along the free path until they meet the respective stop surfaces and push them to a greater or lesser extent, causing the inner sleeve to rotate in one direction and another. These rotational movements are dampened by the resistance to rotation offered by the internal friction elements of the surface of the inner axial passage of the inner sleeve with respect to the peripheral surface of the pivot axis. On the other hand, if the vibrations transmitted by the support element are smaller than said threshold value, the sliding blocking elements move along the free path without encountering the abutment surfaces.

Preferably, the elastic shock absorber is designed so that the torsional force that opposes the rotation of the tilting lever corresponds to 80 to 90% of the load of the oscillating group transmitted by the support element to which the tilting lever is articulated. When the provision of more than one elastic shock absorber is provided, each of them is designed to oppose the proportional torsional force part of the load of the oscillating group.

In accordance with what follows from the foregoing, the present invention makes it possible to reduce the level of vibrations and noise caused by oscillations of the oscillating group, by means of a simple and robust structure damper which also has a great ease of assembly.

Aspects and embodiments of the invention are described below on the basis of schematic drawings, in which

Figure 1 is a front perspective view of a washing machine eligible to incorporate a damping system with an oscillation damper in accordance with the present invention;

Figure 2 is a sectional view along the line A-A- shown in Figure 1;

Figure 3 is a top perspective view of an embodiment of an oscillation damper in accordance with the present invention;

Figure 4 is a rear elevation view corresponding to a first embodiment of the oscillation damper shown in Figure 3;

Figure 5 is a side elevation view of the left rocker lever present in the oscillation damper illustrated in Figure 4;

Figure 6 is a side elevation view of the right rocker lever present in the oscillation damper illustrated in Figure 4;

Figure 7 is a rear elevational view corresponding to a first embodiment of the oscillation damper shown in Figure 3;

Figure 8 is a side elevation view of the left rocker lever present in the oscillation damper illustrated in Figure 7;

Figure 9 is a side elevation view of the right rocker lever present in the oscillation damper illustrated in Figure 7;

Figure 10 is a side perspective view of an embodiment of a radial rotation damper present in the oscillation damper shown in Figure 3;

Figure 11 is a cross-sectional view of the radial damper along the line B-B shown in the figure

Four.

MODES OF CARRYING OUT THE INVENTION

Figures 1 and 2 show an embodiment of a washing machine 9 according to the present invention which, in a conventional manner, comprises a housing 10. The housing 10 comprises a front wall 11 with a loading opening 12 allowing access to the washing drum 13, and which is closed by a loading door 14. Inside the housing 10 there is an oscillating group comprising a washing tank 15 in which a washing drum 13 rotates and having a front mouth facing the loading opening 14. The washing drum 13 comprises a driven pulley 23 connected to a propeller motor 21 by a transmission belt 22. The housing 10 further comprises a rear wall (not shown in the figures), a wall of cover 19, a lower base 20 as well as two side walls 25.

The wash tank 15 is connected to the housing 10 superiorly by means of two support springs 17 that are engaged in respective hooks 18 on opposite sides of the cover wall 19 of the housing 10, and inferiorly through two connected support elements 24 to the base 20 of the housing 10 in two positions close to the respective side walls 25 of the housing 10.

The lower end of each support element 24 is connected to the base 20 of the housing 10 through an oscillation damper 1 comprising a fixed support 2 anchored in the base 20, a first joint 26 comprising a pivot shaft 26 coupled with rotational capacity in the fixed support 2 and at least one tilting lever 5 connected to the pivot axis 3 through a friction damper (not shown in figures 1 and 2). The lower end of the support element 24 is articulated to the tilting lever 5 by means of a second joint 26, while the upper end of each support element 24 is articulated to the washing tank 15 by a third joint 29.

The oscillation dampers 1 are designed to oppose torsional forces that together correspond to 80 to 90% of the load of the oscillating group received by the support elements 24 articulated to the tilting levers 5, while the rest of the load is supported by the support springs 17. The load of the oscillating group is based on the weight of the assembly formed by the washing tank 15, the drum 13 and the motor 21 that form the oscillating group plus the weight of the maximum volume of the washing water present in the washing tank 15 and the maximum possible weight of the clothes present in the drum 13 which, during the rotation of the drum 13 during the washing and spinning process, exert forces that lead to the said oscillations whose transmission to the housing of the Lifting machine is mitigated by using the oscillation damper 1 of the present invention. In a washing machine with a washing capacity of 7 kg of clothes, this oscillating group usually has a weight of 42 to 48 kg and the maximum total weight of water and clothes is usually about 15 kg.

In the embodiment shown in Figures 3 to 11, the oscillation damper 1 comprises a fixed support 2 fixedly mountable on the lower base 20 of the housing 10 of the washing machine 8, a pivot shaft 3 mounted on the support 2, a radial damper 4 pivot mounted on an intermediate part of the pivot shaft 3, a tilting lever 5 integral with the radial damper 4 with two lugs 5, 5b, 5c with free ends 5a articulable to the support element 24, and an elastic shock absorber 6, 6 ' . The elastic shock absorber is designed so that the torsional force that opposes the rotation of the rocker lever 5 corresponds to a proportional part of the load of the oscillating group received by the support element 24 to which the rocker lever 5 is articulated.

The ends of the pivot shaft 3 are respectively mounted in a first end housing 2a and a second end housing 2b of the fixed support 2. As can be seen in Figures 3, 4 and 7, the elastic shock absorber comprises a first helical spring 6 with turns arranged around the pivot axis 3 between the first housing 2a and the radial damper 4 and a second helical spring 6 'with turns arranged around the pivot axis 3 between the second housing 2b and the radial damper 4.

The first end 6a of the first coil spring 6 is connected to the first lug 5b while its second end is connected to the second end housing 2a. Similarly, the second helical spring 6 'is connected by its first end 6a' to the second lug 5c and by its second end 6b 'to the second end housing 2b. In Figure 4 it is shown that the first end 6a, 6a 'of each helical spring 6, 6' are joined together forming an integral elastic damper to give greater stability to the oscillation damper. In turn, the first end 6a, 6a 'of each helical spring 6, 6' is connected to the lugs 5b, 5c close to the pivot axis 3. In this way, the helical springs 6, 6 'are capable of opposing a torsional force to the rotation of the rocker lever 5 caused by the oscillations transmitted by the support element 24.

The free ends 5a of the lugs 5b, 5c comprise two through holes 8 through which the pivot shaft 28 (Figure 2) extends through the second swivel joint 27 by which the support member 24 is articulated to the lugs 5b , 5c that make up the rocker lever 5.

The first end 6a, 6a 'of each helical spring 6, 6' is connected to the rocker lever 5 allowing a limited rotation of the rocker lever 5 without opposing the torsional force. According to what figures 4 to 9 illustrate,

this is achieved because the first end 6a, 6a 'of each helical spring 6, 6' slides in a guide groove 7, 7 'on the rocker lever 5, that is, the first end of the first helical spring 6 is it slides in a first guide groove 7 in the first lug 5b during the limited rotation of the rocker lever 5, and the first end of the second helical spring 6 'slides in a second guide groove 7' in the second lug during the turn limited to the rocker lever 5. The guide grooves 7, 7 'extend perpendicularly with respect to the pivot axis 3.

Each guide groove 7, 7 'comprises an upper guide 7a, 7a', a lower guide 7b, 7b 'and a support wall 7c, 7c' which is disposed between first ends of the upper guide 7a, 7a 'and of the lower guide 7b, 7b ', and on which the first end 6a, 6a' of the helical spring 6, 6 'rests when the rocker lever 5 is subjected to the load of the oscillating group transmitted by the support element 24 to the lever tilting 5. In the embodiment shown in Figures 4 to 6, the guide groove 7, 7 'is a recess comprising an access opening 7e, 7e' between second ends of the upper and lower guides 7a, 7a '; 7b, 7b 'opposite the support wall 7c, 7c'. On the other hand, in the embodiment shown in Figures 7 to 9, the guide groove 7, 7 'is a recess comprising a retaining wall 7d, 7d' disposed between second ends of the upper and lower guides 7a, 7a ' ; 7b, 7b 'opposite the support wall 7c, 7c'.

The radial turning damper 4 comprises an outer bushing 30 with an inner passage 4a and integral with the tilting lever 5, and an inner bushing 31 housed with rotation capacity in the outer bushing 30. The inner bushing 31 comprises an external wall 31a facing each other to an inner wall 30a of the outer sleeve 30 and an axial inner passage 31b in which the internal friction means 32 radially hugging the pivot shaft 3 are exerted radially exerting a frictional force to dampen the rotational movement between the pivot shaft 3 and the inner bushing 31 and, therefore, between the pivot shaft 3 and the outer bushing 30. The internal friction means 32 are four pads of elastic material with cross-section in the form of a circle crown segment inserted each a pressure between four internal equidistant radial projections 31c emerging into the interior passage 4a and the pivot axis treatment 3.

The rotation between the inner bushing 31 and the outer bushing 30 is limited by a turning delimiter system comprising four axial channels 34 of cross section in the form of a circular crown segment each delimited between two radial end stop surfaces 35 located between the inner bushing 31 and outer bushing 30. In the axial channels 34, two turning delimiters 30b, 31b, 33 are housed, in the form of two axial internal projections 30b emerging from opposite sides of the inner wall 30a of the outer bushing 30, two external projections 31b emerging from opposite sides of the external wall 31a of the inner bushing 31, and four sliding locking elements 33 each of which is disposed between one of the internal projections 30b and one of the external projections 31b. The sliding locking elements 33 are also pads of elastic material with cross-section in the form of a circle crown segment each inserted under pressure in the corresponding axial channel 34. The stop surfaces 35 are formed by the opposite axial sides of the internal and external projections 30b, 31b. The sliding locking elements 35 have a smaller radial extension than the axial channels 34 so that they are movable in the axial channel 34 along a free path. limited by said abutment surfaces 35, corresponding to an arc of 1 to 4o, that is, the outer bushing 30 and the inner bushing 31 can rotate between 1 and 4o before the internal friction elements 32 oppose a force of rotation friction between the pivot axis 3 and the outer bushing 30. Thus it is achieved that the oscillations transmitted by the support element 24 which have a intensity greater than a predetermined threshold value, cause the sliding locking elements 33 to travel by the free path until they encounter the respective stop surfaces 35 and push them to a greater or lesser extent, causing the inner sleeve 4 to rotate in one direction and another. These rotational movements are damped by the resistance to rotation offered by the internal friction elements 32 of the surface of the axial inner passage 4a of the inner sleeve 31 with respect to the peripheral surface of the pivot axis 3. On the other hand, if the transmitted vibrations because of the support element 24, they are smaller than said threshold value, the sliding blocking elements 33 move along the free path without encountering the abutment surfaces 33.

Numerical references

1 oscillation damper

2 fixed support

2nd first extreme accommodation

2b second end housing

3 pivot shaft

4 radial swing damper

4th step inside

5 rocker lever

5th free end

5b, 5c lugs

5d, 5e passage opening

6 first coil spring

6 'second coil spring

9 household appliance

6b, 6b 'second end

6th, 6th 'first end

6, 6 'coil spring

7, 7 'guide groove

7th, 7th 'top guide

7b, 7b 'bottom guide

7c, 7c 'support wall

7d, 7d 'retaining wall

7e, 7e 'access opening

8 through hole

9 washing machine

10 housing

11 front wall of the housing

12 loading opening

13 wash drum

14 loading door

15 wash tank

16 axis of rotation of the drum

17 lift springs

18 spring hooks to Cuba

19 deck wall

20 housing base

21 drive motor

22 drive belt

23 driven pulley

24 support element

25 housing side walls

26 first swivel joint

27 second swivel joint

28 pivot shaft

29 third swivel joint

30 outer cap

 30th inner wall of the outer sleeve

 30b internal boss of outer sleeve

 31 inner bushing 31a outer wall of inner bushing 31b external shoulder of inner bushing 31c internal bushing of inner bushing 32 internal friction element 33 sliding locking element 34 axial channel 35 stop surface

Claims (14)

1. Oscillation damper for a household appliance, particularly washer or dryer machine, with a fixed support (2) fixedly mountable on a lower part of the housing (10) of the domestic appliance (9) in which an oscillating group is housed that it comprises a vat (15) in which a drum (13) rotates around an axis of rotation (16); a pivot shaft (3) mounted to the support (2); a radial turning damper (4) mounted on the pivot shaft (3); a tilting lever (5) integral with the radial damper (4), with an articulated free end (5a) to a support element (24) articulated in turn to a lower part of the tank (15) that receives a load from the group oscillating; characterized in that it comprises an elastic shock absorber (6, 6 ') with a first end (6a, 6a') connected to the rocker lever (5) and a second end (6b, 6b ') connected to the fixed support (2), so which opposes a torsional force to the rotation of the rocker lever (5).

2.

Oscillation damper according to claim 1, characterized in that the radial rotation damper (4) is mounted on an intermediate part of the pivot shaft (3); the fixed support (2) comprises a first end housing (2a) and a second end housing (2b) on which the pivot shaft (3) is mounted; The elastic shock absorber comprises at least one metal coil spring (6, 6 ') with turns arranged around the pivot axis (3) and comprises a first coil spring (6) with turns arranged around the pivot axis (3) between the first housing (2a) and the radial damper (4) and a second coil spring (6 ') with turns arranged around the pivot axis (3) between the second housing (2b) and the radial damper (4).

3.

Swing damper according to claim 2, characterized in that the rocker lever (5) comprises two lugs (5b, 5c) articulable to the support element (24); the first helical spring (6) is connected by its first end (6a) to one (5b) of the lugs and by its second end (6b) to the first end housing (2a); the second helical spring (6 ') is connected by its first end (6a') to the other lug (5c) and by its second end (6b ') to the second end housing (2b).

Four.

Oscillation damper according to any one of claims 2 to 3, characterized in that the first end (6a, 6a ') of each helical spring (6, 6') is connected to the rocker lever (5) close to the pivot axis ( 3).

5.

Oscillation damper according to any one of claims 2 to 4, characterized in that the first end (6a, 6a ') of each helical spring (6, 6') is connected to the rocker lever (5) by means of a guide groove ( 7, 7 ') of the rocker lever (5) which allows a limited rotation of the rocker lever (5) without opposing the torsional force.

6.

Oscillation damper according to claim 5, characterized in that the guide groove (7, 7 ') extends perpendicularly with respect to the pivot axis (3); and comprises an upper guide (7a, 7a '), a lower guide (7b, 7b') and a support wall (7c, 7c ') that is disposed between first ends of the upper guide (7a, 7a') and of the lower guide (7b, 7b '), and on which the first end (6a, 6a') of the helical spring (6, 6 ') is supported when the rocker lever (5) is subjected to the load of the received oscillating group by the support element (24) to which the rocker lever (5) is articulated.

7.

Oscillation damper according to claim 6, characterized in that the guide groove (7, 7 ') comprises a retaining wall (7d, 7d') disposed between second ends of the upper and lower guides (7a, 7a '; 7b, 7b ') opposite the support wall (7c, 7c').

8.

Oscillation damper according to claim 6, characterized in that the guiding groove (7, 7 ') is a recess comprising an access opening (7e, 7e') between second ends of the upper and lower guides (7a, 7a ' ; 7b, 7b ') opposite the support wall (7c, 7c').

9.

Oscillation damper according to any one of claims 1 to 8, characterized in that the elastic damper is designed so that the torsional force that opposes the rotation of the rocker lever (5) corresponds to 80 to 90% of the load of the oscillating group transmitted by the support element (24) to which the rocker lever (5) is articulable.

10.

Oscillation damper according to any one of the preceding claims, characterized in that the radial rotation damper (4) comprises an outer bushing (30) integral with the rocker lever (5); the outer bushing (30) has rotational movement capacity with respect to the pivot axis (3) and; The radial rotation damper (4) further comprises internal friction means (32) that radially embrace the pivoting axis (3) exerting a frictional force to dampen the rotational movement between the pivot axis (3) and the outer sleeve ( 30).

eleven.

Oscillation damper according to claim 10, characterized in that the radial rotation damper (4) comprises an inner bushing (31) housed in the outer bushing (30) with turning capacity, the inner bushing (31) comprising an outer wall (31) 31a) facing an inner wall (30a) of the outer bushing (30) and an axial inner passage (4a) in which the internal friction means (32) are radially arranged exerting a frictional force at least on the inner bushing ( 31); the rotation between the inner bushing (31) and the outer bushing (30) is limited by a turning boundary system comprising at least one axial channel (34) located between the inner bushing (31) and the outer bushing

(30) and at least one turning delimiter element (30b, 31b, 33) located in the axial channel (34); the axial channel (34) has a cross section in the form of a circular crown segment delimited between two radial end stop surfaces (35); each turning delimiter element (30b, 31b, 33) is selected from protrusions (30b) emerging from the inner wall of the outer sleeve, protrusions (31b) emerging from the outer wall of the inner sleeve, sliding blocking elements (33), and combinations thereof; each projecting element (30b, 31b) is movable in the corresponding channel (34) so that, when turning each other the outer bushing (30) and the inner bushing (31) each projecting element (30b, 31b) has a free travel in the axial channel (34) limited by said stop surfaces (35).

12.

Oscillation damper according to claim 11, characterized in that the free path of rotation between the outer bushing (30) and the inner bushing (31) corresponds to an arc of 1 to 4 °.

13.

Household appliance, particularly washer or dryer machine, comprising a housing (10) that houses an oscillating group comprising a washing tank (15) in which a washing drum (13) driven by a motor (21) rotates, being the tank (15) connected with the housing (10) superiorly by means of at least one pair of support springs (17) and inferiorly through at least two support elements (24) connected to an oscillation damping system, the support element (24) articulated to the housing (10) with collation of at least one joint (26, 27, 29) comprising a radial damper (4), characterized in that it comprises at least one oscillation damper (1) according to a any of claims 1 to 12.

14.

Domestic appliance according to claim 13, characterized in that the damping system comprises a plurality of oscillation dampers (1) mounted on opposite sides of the housing

(11) and because the oscillation dampers (1) are designed to oppose torsional forces that together correspond to 80 to 90% of the load of the oscillating group received by the support elements (24) articulated to the tilting levers (5) .