A bearing (4) includes an outer ring (6), rolling elements (5) and a two-part inner ring (A). The two-part inner ring (A) includes a first part (1) having a radially outer surface (11) and an inner bore (12). Furthermore, the two-part inner ring (A) includes a second part (2) having a radially inner
A bearing (4) includes an outer ring (6), rolling elements (5) and a two-part inner ring (A). The two-part inner ring (A) includes a first part (1) having a radially outer surface (11) and an inner bore (12). Furthermore, the two-part inner ring (A) includes a second part (2) having a radially inner surface (21) and at least one raceway (22) for rolling elements. The radially outer surface (11) of the first part (1) essentially matches the radially inner surface (21) of the second part (2). A cavity (3), which in use acts as a pressure chamber, is located between the first and second parts (1, 2). When pressurizing the cavity (3), a relative axial movement between the first and second parts (1, 2) is accomplished.
대표청구항▼
1. A bearing comprising: an outer ring,a plurality of rolling elements,a two-part inner ring including:a first part having a radially outer surface and an inner bore, the radially outer surface having at least two portions of different diameters axially spaced apart,a second part having a radially i
1. A bearing comprising: an outer ring,a plurality of rolling elements,a two-part inner ring including:a first part having a radially outer surface and an inner bore, the radially outer surface having at least two portions of different diameters axially spaced apart,a second part having a radially inner surface and at least one raceway for rolling elements, the at least one raceway being located on an outer surface, the radially inner surface having at least two portions of different diameters axially spaced apart and substantially mating with the radially outer surface of the first part,a ring shaped element disposed between the first and second parts and at least partly within an axial width of the outer ring and located at an axial end of at least one of the first and second parts; anda cavity located between the first and second parts and at least partly within the axial width of the outer ring, the cavity extending at least partly in a circumferential direction and configured to provide a pressure chamber, the cavity being bounded by a first surface on the first part and a second surface on the second part axially spaced apart, and wherein normal vectors of the first and second surfaces have vector components in axial direction, such that when pressurizing the cavity, a relative axial movement between the first and second parts is accomplished. 2. The bearing, according to claim 1, wherein at least one of the radially outer surface of the first part and the radially inner surface of the second part include at least one of: an essentially conical shape, and a plurality of essentially conical shapes extending in an axial direction. 3. The bearing, according to claim 1, wherein the ring shaped element is located at an axial end of at least one of the two parts and an axially inner side of the ring shaped element is partly bounding the cavity. 4. The bearing, according to claim 1, further comprising a sealing element disposed in the cavity at an axial end of the cavity. 5. The bearing, according to claim 1, further comprising at least one fluid duct having an inlet and an outlet, the fluid duct extending from a surface of any of the first and second parts into the pressure chamber. 6. The bearing according to claim 1, further comprising, at least one fluid duct having an inlet and an outlet, the fluid duct extending from a surface of any of the first and second parts to at least one contact surface between the radially outer surface and the radially inner surface. 7. The bearing, according to claim 6, wherein the fluid duct further extends in at least one fluid groove at the at least one contact surface in at least one of an axial direction of the contact surface and a circumferential direction of the contact surface. 8. A method for mounting a bearing to a shaft, comprising the steps of: providing a bearing including an outer ring, a plurality of rolling elements, a two-part inner ring including a first part having a radially outer surface and an inner bore, the radially outer surface having at least two portions of different diameters axially spaced apart, a second part having a radially inner surface and at least one raceway for rolling elements, the at least one raceway being located on an outer surface, the radially inner surface having at least two portions of different diameters axially spaced apart and substantially mating with the radially outer surface of the first part;disposing a ring shaped element between the first and second parts and at least partly within an axial width of the outer ring with the ring shaped element located at an axial end of at least one of the first and second parts;forming a cavity located between the first and second parts and at least partly within the axial width of the outer ring, the cavity extending at least partly in a circumferential direction and configured to provide a pressure chamber, the cavity being bounded by a first surface on the first part and a second surface on the second part axially spaced apart, and wherein normal vectors of the first and second surfaces have vector components in axial direction, such that when pressurizing the cavity, a relative axial movement between the first and second parts is accomplished;attaching the bearing onto the shaft, wherein the inner bore is mounted onto an outer peripheral surface of the shaft;moving the bearing to an axial position on the shaft; andpressurizing the cavity, leading to driving up the second part onto the radially outer surface of the first part. 9. A method for dismounting a bearing, comprising the steps of: providing a bearing including an outer ring, a plurality of rolling elements: a two-part inner ring including a first part having a radially outer surface and an inner bore, the radially outer surface having at least two portions of different diameters axially spaced apart, a second part having a radially inner surface and at least one raceway for rolling elements, the at least one raceway being located on an outer surface, the radially inner surface having at least two portions of different diameters axially spaced apart and substantially mating with the radially outer surface of the first part;disposing a ring shaped element between the first and second parts and at least partly within an axial width of the outer ring with the ring shaped element located at an axial end of at least one of the first and second parts;forming a cavity located between the first and second parts and at least partly within the axial width of the outer ring, the cavity extending at least partly in a circumferential direction and configured to provide a pressure chamber, the cavity being bounded by a first surface on the first part and a second surface on the second part axially spaced apart, and wherein normal vectors of the first and second surfaces have vector components in axial direction, such that when pressurizing the cavity, a relative axial movement between the first and second parts is accomplished, the inner bore being disposed about the shaft;pressurizing the cavity with a fluid medium in order to obtain a relative axial movement between the first and second parts, leading to driving off the second part from the radially outer surface of the first part, and thereby decreasing a radial pressure between the shaft and the first part; anddetaching the bearing from the shaft. 10. The method according to claim 9: wherein the bearing further includes at least one fluid duct having an inlet and an outlet, the fluid duct extending from a surface of any of the first and second parts to at least one contact surface between the radially outer surface and the radially inner surface and the inner bore is attached onto an outer peripheral surface of the shaft, andfurther comprising the step of pressurizing the fluid duct, such that the second part is driven off the first part by an axial movement. 11. The method according to claim 10: wherein the normal vectors of the first surface present a component in axial direction and in opposite direction to an axial component of at least one normal vector of the radially outer surface, andfurther comprising the step of pressurizing the cavity such that an axial force acts on the second part in opposite direction to an axial force acting on the second part resulting from the pressure from the pressurized fluid duct such that the second part is driven off the first part in a controlled manner. 12. A method for adjusting a bearing clearance comprising the steps of: providing a bearing including an outer ring, a plurality of rolling elements;a two-part inner ring including a first part having a radially outer surface and an inner bore, the radially outer surface having at least two portions of different diameters axially spaced apart, a second part having a radially inner surface and at least one raceway for rolling elements, the at least one raceway being located on an outer surface, the radially inner surface having at least two portions of different diameters axially spaced apart and substantially mating with the radially outer surface of the first part, anddisposing a ring shaped element between the first and second parts and at least partly within an axial width of the outer ring with the ring shaped element located at an axial end of at least one of the first and second parts;forming a cavity located between the first and second parts and at least partly within the axial width of the outer ring, the cavity extending at least partly in a circumferential direction and configured to provide a pressure chamber, the cavity being bounded by a first surface on the first part and a second surface on the second part axially spaced apart, and wherein normal vectors of the first and second surfaces have vector components in axial direction, such that when pressurizing the cavity, a relative axial movement between the first and second parts is accomplished, the inner bore being disposed about an outer peripheral surface of the shaft; andpressurizing the cavity such that a relative axial movement is accomplished, thereby driving the second part to an axial position on the first part, in order to adjust the bearing clearance.
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