DE102009011697A1 - Decoupled belt pulley for use in starter of drive assembly of road vehicle, has primary mass connected with shaft, secondary mass connected with primary mass by flexible coupling, and bearings arranged between couplings - Google Patents

Abstract

The belt pulley (3) has a primary mass (10) connected with a shaft provided running along a rotation axis (8). A secondary mass (11) is rotatably moved in relation to the primary mass by a flexible coupling (12). Bearings (26a, 26b) provide relative motion of the masses in circumferential direction. The secondary mass is cooperated at outer circumference of a belt so that torque is transferred between the secondary mass and the belt. The secondary mass is connected with the primary mass by another flexible coupling (12a). The bearings are arranged between the couplings. An independent claim is also included for a method for manufacturing a decoupled belt pulley.

Description

The The invention relates to a decoupled pulley having a primary mass, the rotationally fixed with a shaft extending along a rotation axis is connectable, and with a secondary mass, opposite the primary mass is rotatable and the over an elastic coupling connected to the primary mass is.

used is the decoupled pulley especially in drive units of motor vehicles, especially road vehicles. As a rule, the shaft is the crankshaft of the drive unit. about The pulley can also have external units and facilities are powered. Examples are for that are generators for generating electrical energy, pumps and / or Starter of the drive unit.

Of the Term belt includes in particular the so-called V-ribbed belt but also a toothed belt (in which case the keyway profile through a sprocket can be replaced) with a.

such Pulleys are in terms of transmission of mechanical Vibrations between the outer circumference of the secondary mass, at which the belt acts on the one hand and the shaft on the other to dampen, d. H. decoupling vibration. The Power transmission or torque conversion therefore takes place at least for the most part about an elastic Coupling the pulley, which is usually radially inward on the Primary mass attacks and radially outside of the secondary mass attacks.

Problematic However, there are the considerable mechanical loads the elastic material of the coupling and the material transition between the elastic material and other parts in the Usually made of metal. Usually this is elastic Vulcanized material. With vibrations and forces, which act exclusively in the radial direction, are the Clutches usually permanently usable. However, too Shearing forces and corresponding vibrations occur at which the forces additionally act in the axial direction. This can be without additional measures the Change the outer circumference of the pulley, so that the attacking on the outer circumference belt in undesirable Way is claimed.

Furthermore It is known to use the pulley in a single component to combine a torsional vibration damper. The damper serves to dampen torsional vibrations (torsional vibrations) the wave.

Such a combination is for example from the EP 1 266 152 B1 known. The combination has an integrated viscous torsional vibration damper and a bearing and a coupling made of elastomeric material for relatively rotatable and circumferentially the secondary mass elastic support of the secondary mass relative to the damper housing (the primary mass). Alternatively or additionally, the combination instead of the viscosity torsional vibration damper have a damper made of rubber-elastic material.

at The combination should be the vibration natural frequencies of the damper and the coupling far enough apart so that no mutual Influencing takes place. Is the damping characteristic given the damper, but this restricts the Possibilities of construction of the clutch.

The Secondary mass is at its inward radial direction Edge with at least one bearing (usually a plain bearing, conceivable However, a rolling bearing is provided), the one or the Relative movement of the secondary mass and the primary mass in the circumferential direction (i.e., in the rotational direction about the rotation axis the wave) allows / enable and leads / lead. The at least one bearing can under certain conditions of use of a vehicle, its drive unit with the decoupled pulley is impaired in its function. In particular, dirt and / or water between bearing parts and / or between the bearing and other parts of the pulley. Such conditions are z. B. met if a Wheeled vehicle in the area, outside public Roads are operated and / or over with water covered ground drives.

It It is an object of the present invention to provide a decoupled pulley indicate the bearing between primary mass and secondary mass effectively protected against the entry of dirt and / or water is and where the elastic decoupling between primary mass and secondary mass has a long life.

According to a basic idea of the present invention, the bearing, which allows relative movement of the secondary mass and the primary mass in the circumferential direction, is arranged between two elastic couplings, the secondary mass and the primary mass being connected to one another via both elastic couplings. In particular, the couplings are annular and configured at least approximately rotationally symmetrical about the axis of rotation of the shaft and offset from each other in the axial direction. In this context, the arrangement of the camp "between" to understand the clutches so that the bearing is located at an axial position and in opposite directions from this axial position is at least a portion of the first and the second elastic coupling. However, this does not mean that a straight line that is parallel to the rotation axis connects a portion of the first elastic coupling with the bearing and a portion of the second elastic coupling. Rather, the camp z. B. closer to the axis of rotation than the radially inner ends of the elastic couplings.

The Elastic couplings do not have to be complete either lie in axial ranges, from the perspective of the axial position of the camp opposite each other. Rather, z. B. one of the two elastic couplings in their course in the radial direction go through different axial areas. For example, this may be radial inside end of a clutch in the same axial region like the radially outer end of the other Clutch are located.

In However, in all cases, the bearing is preferably of the Both elastic couplings, the primary mass and the Secondary mass closed (ie in the manner of a housing) shielded against the environment. Therefore, neither dirt nor water can get into the local area of the camp.

Further makes the use of two elastic couplings a special durable construction. The effects of shear forces that act in the axial direction on one of the clutches are by the other clutch mitigated. Therefore, the individual couplings z. B. made thinner in the axial direction which reduces the space required compared to the use of only one clutch not or only slightly larger is.

• • einer Primärmasse, die drehfest mit einer entlang einer Rotationsachse verlaufenden Welle verbindbar ist,
• • einer Sekundärmasse, die gegenüber der Primärmasse drehbeweglich ist und die über eine erste elastische Kupplung mit der Primärmasse verbunden ist,
• • zumindest einem Lager, das eine Relativbewegung der Sekundärmasse und der Primärmasse in Umfangsrichtung ermöglicht,

wobei die Sekundärmasse ausgestaltet ist, an ihrem Außenumfang mit einem Riemen zusammenzuwirken, sodass ein Drehmoment zwischen der Sekundärmasse und dem Riemen übertragbar ist,
wobei die Riemenscheibe eine zweite elastische Kupplung aufweist, über die die Sekundärmasse mit der Primärmasse verbunden ist, und
wobei das Lager zwischen der ersten und der zweiten elastischen Kupplung angeordnet ist.In particular, the following is proposed: A decoupled pulley, with

• A primary mass, which is non-rotatably connectable to a shaft running along a rotation axis,
• A secondary mass, which is rotatable relative to the primary mass and which is connected to the primary mass via a first elastic coupling,
• At least one bearing which allows a relative movement of the secondary mass and the primary mass in the circumferential direction,

wherein the secondary mass is configured to cooperate with a belt on its outer circumference such that a torque is transferable between the secondary mass and the belt,
wherein the pulley has a second elastic coupling, via which the secondary mass is connected to the primary mass, and
wherein the bearing is disposed between the first and second elastic couplings.

Preferably meets the bearing, that between the two elastic couplings is arranged, several storage functions, in particular leadership of the relative rotational movement of the primary mass and the secondary mass both in the axial direction, as well as in the radial direction. Under the guidance of the rotational movement in the axial direction is understood that the bearing a relative displacement of the components adjacent to the bearing in the axial direction limited to a permitted play while the relative rotational movement is possible. It will continue preferred that the bearing the rotational movement in the axial direction both in the one axial direction and in the opposite direction leads.

The elastic couplings can be made in particular of rubber be. "Rubber" is used in the present specification understood any elastomeric material, regardless of whether it is made of natural materials such. B. natural rubber won and / or made of plastic. For example, the couplings are and possibly existing elastomeric elements of vibration dampers of a polar rubber material, preferably a hydrogenated one Nitrile butadiene rubber compound (HNBR). It can but alternatively, for example, EPDM (ethylene-propylene-diene rubber), ENR (Epoxidized Natural Rubber), EVA (Ethylene Vinyl Acetate), NBR (Nitrile-butadiene rubber), AEM (ethylene-acrylate rubber) or ACM (polyacrylate rubber) can be used.

In addition to the elastic coupling, the pulley may have a further damping device for damping torsional vibrations, for. B. a rotatably mounted in a viscous or viscoelastic liquid damping mass. In particular, such a viscous damper for damping torsional vibrations of the shaft is integrated into the primary mass. Alternatively or additionally, the damping device may comprise a rubber damper. In particular, the primary mass can be connected via a rubber-elastic element with a tertiary mass, so that the primary mass, the rubber-elastic element and the tertiary mass form a vibration damper for damping torsional vibrations. The tertiary mass and the secondary mass can be mounted rotatably about the rotation axis about the bearing against each other. Alternatively, the secondary mass and the primary mass can be rotatably supported by the bearing against each other about the rotation axis and the tertiary mass is only to the Pri poorly coupled.

The Use of two clutches solves the above Problematic that the movement behavior of the vibration damper briefly leads to strong stresses in the elastic coupling. Two clutches are more stable and it has been shown that the Effects of the movement behavior of the vibration damper become negligible on the integrity of the coupling material.

Especially the secondary mass may have an area that is extends from radially outward to radially inward and at its radially inward end about the bearing rotatably on the primary mass is supported. This can be this Area of secondary mass completely or largely directly between the opposing couplings run.

The radially inward end of the area of the secondary mass, which extends from radially outside to radially inside, may be at equal or less radial distance from the axis of rotation lie like a radially inner end of the first and / or second elastic coupling. At about the same radial position can the primary mass at its outer periphery a substantially have cylindrical surface. The production of the primary mass is thus possible in a simple manner. Furthermore supports the radially inner end of the secondary mass in this case at approximately the same radial position as the elastic Clutches on the outer circumference of the primary mass (above the warehouse (s)). Therefore, the camp lies or lie the bearings approximately centrally at the same radial position as the inner ends the clutch and the bearing (s) is / are only in very small Circumference uneven, acting in the radial direction Suspended bearing forces. The warehouse (s) will therefore be less stressed and the life is increased.

alternative For example, the primary mass may have an area that extends between the opposing couplings of extends radially inward radially outward, wherein the Secondary mass on the bearing rotatably on the radially outer end of this area is supported.

In turn Alternatively, the bearing between the opposing Couplings may be arranged so that a relative rotational movement of a first area and a second area around the axis of rotation is stored. The first area is an area of the primary mass, extending between the opposing couplings extends radially inward to radially outward and at its radially outer end cooperates with the bearing. The second area is an area of secondary mass, the from radially outside to radially inside between each other extends opposite couplings, wherein at the radial inside the end of the second region, the bearing is arranged.

In turn alternatively or additionally it is possible that a tertiary mass to form a vibration damper in the space between the opposing ones Couplings is arranged and a rubber-elastic element with a radially outer end of the primary mass connected is. The primary mass and the tertiary mass Therefore, together with the rubber-elastic element form a torsional vibration damper. At a radially outer end of the tertiary mass the bearing is arranged, which determines the relative rotational movement of Primary mass and the secondary mass around the axis of rotation allows.

The radially outer end of one of the clutches (preferably Both couplings) can be pointing to the radially inward Surface of an outer area of the Support secondary mass. This outer one Area can be designed on its outer circumference, with to cooperate with the belt. For example, on the outer circumference a corresponding Keilnutenprofil provided.

A particularly easy and inexpensive to produce pulley, which also has a particularly long life, is with the following configuration achieved: The first and the second elastic coupling are symmetrical designed to a plane of symmetry, which is between the elastic Couplings is located and perpendicular to the axis of rotation. Alternatively or additionally, the first and the second elastic coupling the same elastic properties and natural frequencies. Due to the symmetrical design, the couplings in the same Ways claimed and unilateral stresses of or Stock avoided.

The second clutch or an element with which the second clutch through Vulcanization has been linked in the axial direction of the bearing by a radially projecting portion the primary mass or the secondary mass separated be. In particular, the second clutch or with this vulcanization-connected element at the projecting portion abut and can be on the opposite side of the projecting area the bearing, in particular a plain bearing, issue.

In the case of the region of the secondary mass extending between the opposing couplings from radially outside to radially inside extends, the radially projecting portion is a radially outwardly projecting portion of the primary mass. In the case of the region of the primary mass extending radially inward between the opposing couplings, the radially projecting portion is a radially inwardly projecting portion of the secondary mass.

The other clutch, the first clutch, can be directly in the axial direction adjoin the bearing or alternatively, an element with which the first coupling has been connected by vulcanization, in axial Direction directly adjacent to the camp.

at The production of the pulley can therefore first the Secondary mass over the at least one camp with coupled to the primary mass and then the first clutch can be arranged so that it has the primary mass connects with the secondary mass.

• • eine Primärmasse, die drehfest mit einer entlang einer Rotationsachse verlaufenden Welle verbindbar ist, über eine erste elastische Kupplung mit einer Sekundärmasse, die gegenüber der Primärmasse drehbeweglich ist, verbunden wird,
• • zumindest ein Lager, das eine Relativbewegung der Sekundärmasse und der Primärmasse in Umfangsrichtung ermöglicht, zwischen der Primärmasse und der Sekundärmasse angeordnet wird,
• • wobei die Sekundärmasse ausgestaltet ist, an ihrem Außenumfang mit einem Riemen zusammenzuwirken, sodass ein Drehmoment zwischen der Sekundärmasse und dem Riemen übertragbar ist,
• • wobei die Sekundärmasse über eine zweite elastische Kupplung mit der Primärmasse verbunden wird,

sodass das Lager zwischen der ersten und der zweiten elastischen Kupplung angeordnet ist.Further, the scope of the invention includes a method for producing a decoupled pulley, in particular a pulley in one of the embodiments described above and / or below, wherein

• A primary mass which can be connected in a rotationally fixed manner to a shaft running along an axis of rotation is connected via a first elastic coupling to a secondary mass, which is rotatable relative to the primary mass,
• At least one bearing which allows a relative movement of the secondary mass and the primary mass in the circumferential direction, is arranged between the primary mass and the secondary mass,
• Wherein the secondary mass is configured to cooperate with a belt on its outer circumference, so that a torque can be transmitted between the secondary mass and the belt,
• Wherein the secondary mass is connected to the primary mass via a second elastic coupling,

so that the bearing is arranged between the first and the second elastic coupling.

embodiments in the invention will now be with reference to the attached Drawing described. The figures of the drawing show:

1 an axial section through a decoupled pulley, the cutting plane containing the axis of rotation of the shaft with which the primary mass of the pulley rotatably connected, and

2 an axial section through a second embodiment of a decoupled pulley.

1 shows an axis of rotation at the bottom of the picture 8th to get the one in 1 not shown shaft rotates. When the in 1 illustrated decoupled pulley 3 mounted on the shaft is the axis of rotation 8th also the axis of rotation of the pulley 3 ,

1 shows a section through the pulley 3 only on one side of the axis of rotation 8th , Since the components of the pulley 3 substantially rotationally symmetrical to the axis of rotation 8th would be at a complete cross-sectional view below the axis of rotation 8th lying part axisymmetric with respect to the axis of rotation 8th to the in 1 be shown part. That the essential parts of the pulley, primary mass, secondary mass, bearings and couplings as well as possibly torsional vibration dampers are substantially rotationally symmetrical to the axis of rotation, preferably also applies to other embodiments of the decoupled pulley.

Top in 1 you can see the profiled outer circumference of the secondary mass 11 the pulley 3 , In a known manner can there in the areas 31 . 32 two V-ribbed belts are arranged and with the pulley 3 interact so that between the belt on the one hand and the pulley 3 on the other hand forces in the circumferential direction, ie in the direction of rotation about the axis of rotation 8th can be transmitted. Both the belts can drive the pulley and vice versa.

The secondary mass 11 has a substantially T-shaped profile. At the transverse leg of the T, at the top of which the outer circumference of the pulley 3 and thus also the outer circumference of the secondary mass 11 There are two clutches 12 . 12a fixed radially on the inside. To simplify the manufacture, the clutches are 12 . 12a in the embodiment at its radially outer and inner ends first with a metal bushing 27 . 27a ; 28 . 28a connected, in particular connected by vulcanization. When mounting the pulley 3 be through the sockets 27 . 28 such as 27a . 28a with the rubber-elastic material of the couplings 12 . 12a units formed radially on the outside with the underside of the transverse leg of the T of the secondary mass 11 and radially inside with the outer periphery of the primary mass 10 connected.

The radial longitudinal leg of the T of the secondary mass 11 is with the reference numeral 21 designated. He points to his radially inward end 22 two L-shaped bearing elements 26a . 26b on, stuck to the longitudinal leg 21 are attached, z. B. have been molded using plastic molds known per se as plastic parts. However, the bearing elements can also z. B. metal parts, whose from the surface of the secondary mass 11 groundbreaking outer surfaces with plastic, z. As PTFE (polytetrafluoroethylene) are coated. The L-shaped configuration of the bearing elements 26a . 26b allows simultaneous storage in the radial and axial directions. The bearing elements 26 are designed as parts of a plain bearing. Basically, the use of a rolling bearing would be possible or separate bearings for axial and radial bearing.

The primary mass 10 has at its radially outer outer periphery a projection 17 on. In the room to the left of the projection 17 becomes the unit with the second clutch 12a and the jacks 27a . 28a brought in. First, however, is the secondary mass 11 with the bearing elements 26a . 26b from the right in the axial direction over the outer circumference of the primary mass 10 pushed until the short leg of the L-shaped bearing element 26a on the lateral, axially oriented edge of the projection 17 abuts. Subsequently, first the first clutch 12 or the second clutch 12a or both clutches are mounted simultaneously. The first clutch 12 together with the sockets 27 . 28 is from the right in the axial direction in the annular, of the transverse leg of the secondary mass 11 and the outer circumference of the primary mass 10 formed receiving space until the socket 28 on the right L-shaped bearing element 26b abuts.

How out 1 recognizable, is the camp 26 hermetically shielded from the outside world. The transverse leg of the T of the secondary mass 11 , the units from the rubber couplings 12 . 12a and their jacks 27 . 27a ; 28 . 28a form an inside hollow ring around the axis of rotation 8th in which the longitudinal leg 21 the secondary mass 11 together with the bearing elements arranged thereon 26a . 26b is arranged. The rotationally symmetrical bearing elements 26 therefore allow a relative rotation of the secondary mass 11 and the primary mass 10 around the axis of rotation 8th , where Dregehschläge from a neutral position in which the rubber couplings 12 . 12a no torque between the secondary mass 11 and the primary mass 10 exercise, are possible. Because of the elastic properties of the couplings 12 . 12a lead such Dregehschlägen from the neutral position but that a restoring force or a return of the torque again to reach the neutral position of the secondary mass 11 and the primary mass 10 relative to each other leads. As a rule, vibrations occur around the neutral position, while the entire pulley 3 around the axis of rotation 8th rotates.

Moreover, from the 1 clearly recognizable that the transverse leg of the T of the secondary mass 11 very stable at the opposite ends of the couplings 12 . 12a against the outer circumference of the primary mass 10 is supported. In combination with the double-L-shaped bearing 26 This leads to a very stable, against axial shear forces resistant configuration, so that both the life of the couplings 12 . 12a as well as the bearing elements 26 is very high. The belt or straps are less stressed. The noise is minimized. The bearing performs the rotational movement in the axial direction in both the axial direction and in the opposite direction.

The pulley is therefore particularly well suited for use in off-road vehicles. It is both the bearing elements 26 Protected against ingress of water and dirt, as well as withstands the pulley 3 the special mechanical stresses when using vehicles in the field.

At the in 1 shown pulley modifications can be made. For example, the rubber elements of the couplings must 12 . 12a not substantially in the radial direction between the primary mass 10 and the secondary mass 11 extend. Rather, the outer circumference, z. B. the transverse leg of the T, the secondary mass 11 in the axial direction against the outer circumference of the primary mass 10 be offset, so that at least one of the couplings extends in its course from radially inward to radially outward also in the axial direction. Alternatively or additionally, in particular with the primary mass via a rubber-elastic or viscoelastic coupling a flywheel (tertiary mass) may be connected.

Further the outer circumference of the secondary mass can be different be designed. In particular, the profiling can be configured be that only one belt interacts with the secondary mass.

2 shows a second embodiment of a decoupled pulley. In the following, only the differences to the construction that are described in 1 is shown. The primary mass 50 has one between the couplings 12a . 12 from radially inward to radially outward extending region 51 on, at its radially outer end via a rubber-elastic element 53 with a tertiary mass 55 connected is. The primary mass 50 , the rubber-elastic element 53 and the tertiary mass 55 form a torsional vibration damper for damping torsional vibrations of the shaft and the rotatably connected parts.

The tertiary mass 55 that like the rubber-elastic element 53 is substantially rotationally symmetrical with respect to the axis of rotation 8th , Is at its radially outer outer periphery via a bearing element 56a , which is also substantially rotationally symmetrical, against the radially inward circumferential region of the secondary mass 61 stored. This allows a relative rotational movement of the secondary mass 61 and the tertiary mass 55 around the axis of rotation 8th , Consequently, there is also a relative rotational movement of the primary mass 50 and the secondary mass 61 possible.

The secondary mass is therefore in contrast to the embodiment according to 1 not equipped with a radially extending from outside to inside area, but which may be present in a modified embodiment.

For the pulley according to 2 is a radially projecting area 57 provided, however, in contrast to the embodiment according to 1 radially inward from the inside of the secondary mass 61 projects. However, it has substantially the same function as the radially outwardly projecting portion 17 the primary mass 10 according to 1 , At the in 2 right-facing surface of the projection 57 there is an L-shaped bearing element 56a , The second bearing element 56b However, is not designed L-shaped, but I-shaped, and serves only the axial storage of the possible rotational movement between the tertiary mass 55 and the radially outer end of the clutch 12 or the thus firmly connected sleeve 27 ,

Because in that by the primary mass 50 , the two clutches 12 . 12a and the secondary mass 61 formed outwardly shielded interior both the bearing 56a . 56b as well as the rubber-elastic element 53 located, these parts are protected against contamination. Regarding the couplings 12 . 12a and the way the clutches affect the primary mass 50 and the secondary mass 61 connect, the construction is according to 2 as stable as the construction according to 1 ,

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• EP 1266152 B1 [0007]

Claims (13)

Decoupled pulley ( 3 ), with • a primary mass ( 10 ) rotationally fixed with one along a rotation axis ( 8th ) extending shaft is connectable, • a secondary mass ( 11 ) compared to the primary mass ( 10 ) is rotatable and via a first elastic coupling ( 12 ) with the primary mass ( 10 ), • at least one warehouse ( 26a . 26b ), which is a relative movement of the secondary mass ( 11 ) and the primary mass ( 10 ) in the circumferential direction, the secondary mass ( 11 ) is configured to cooperate on its outer circumference with a belt, so that a torque between the secondary mass ( 11 ) and the belt is transferable, wherein the pulley ( 3 ) a second elastic coupling ( 12a ), over which the secondary mass ( 11 ) with the primary mass ( 10 ) and the bearing ( 26a . 26b ) between the first ( 12 ) and the second ( 12a ) elastic coupling is arranged. Decoupled pulley according to the preceding claim, wherein the secondary mass ( 11 ) an area ( 21 ), which extends from radially outward to radially inward and at its radially inner end ( 22 ) over the camp ( 26a . 26b ) rotatably on the primary mass ( 10 ) is supported. Decoupled pulley according to the preceding claim, wherein the radially inner end ( 22 ) at equal or less radial distance from the axis of rotation ( 8th ) is like a radially inner end of the first and / or second elastic coupling ( 12 . 12a ). Decoupled pulley according to one of the preceding claims, wherein the first and the second elastic coupling ( 12 . 12a ) are configured symmetrically to a plane of symmetry which extends between the elastic couplings ( 12 . 12a ) and perpendicular to the axis of rotation ( 8th ) runs. Decoupled pulley according to one of the preceding claims, wherein the first and the second elastic coupling ( 12 . 12a ) have the same elastic properties and natural frequencies. Decoupled pulley according to one of the preceding Claims, wherein in the primary mass a viscosity damper integrated for damping torsional vibrations of the shaft is. Decoupled pulley according to one of the preceding claims, wherein the primary mass ( 50 ) via a rubber-elastic element ( 53 ) with a tertiary mass ( 55 ), so that the primary mass ( 50 ), the rubber-elastic element ( 53 ) and the tertiary mass ( 55 ) form a vibration damper for damping torsional vibrations. Decoupled pulley according to the preceding claim, a radially inward to radially outwardly extending region ( 51 ) of the primary mass ( 50 ) at its radially outer end via the rubber-elastic element ( 53 ) with the tertiary mass ( 55 ) connected is. Decoupled pulley according to one of the two preceding claims, wherein the tertiary mass ( 55 ) and the secondary mass ( 61 ) rotatable relative to each other through the bearing ( 56 ) are stored. Decoupled pulley according to one of the three preceding claims, wherein the tertiary mass ( 55 ) and the rubber-elastic element ( 53 ) from the primary mass, the couplings ( 12 . 12a ) and the secondary mass ( 61 ) are shielded from the environment. Decoupled pulley according to one of the preceding claims, wherein the second clutch or an element ( 28a ), with which the second clutch ( 12a ) has been bonded by vulcanization, in the axial direction through a radially projecting region ( 17 ) of the primary mass ( 10 ) from the warehouse ( 26a . 26b ) is disconnected. Decoupled pulley according to one of the preceding claims, wherein the first clutch or an element ( 28 ), with which the first clutch ( 12 ) has been connected by vulcanization, in the axial direction of the bearing ( 26b ) adjoins. Method for producing a decoupled pulley ( 3 ), in particular a pulley according to one of the preceding claims, wherein • a primary mass ( 10 ) rotationally fixed with one along a rotation axis ( 8th ) extending shaft, via a first elastic coupling ( 12 ) with a secondary mass ( 11 ) compared to the primary mass ( 10 ) is rotatable, is connected, • at least one bearing ( 26a . 26b ), which is a relative movement of the secondary mass ( 11 ) and the primary mass ( 10 ) in the circumferential direction, between the primary mass ( 10 ) and the secondary mass ( 11 ), whereby the secondary mass ( 11 ) is configured to cooperate on its outer circumference with a belt, so that a torque between the secondary mass ( 11 ) and the belt is transferable, • whereby the secondary mass ( 11 ) via a second elastic coupling ( 12a ) with the primary mass ( 10 ), so that the warehouse ( 26a . 26b ) between the first ( 12 ) and the second ( 12a ) elastic coupling is arranged.