A sliding bearing includes at least one bearing inner ring and at least one bearing outer ring configured to rotate relative to each other about an axis (a), where the rings each include at least one sliding surface, the sliding surfaces being configured to slide along each other, and where the contact surface formed by the mutually contacting sliding surfaces has a maximum contact diameter (D.sub.K). At least parts of the sliding surfaces in a radial section have a radius of curvature (r.sub.B), the radius of curvature (r.sub.B) has a centerpoint (M) located at an offset (b) from the axis (a), and the offset (b) is at least 5% of the radius of curvature (r.sub.B).

The invention relates to a method for producing a bi-material sliding bearing (1) whereby a metal sliding layer (3) of at least two different particle types is deposited under reduced pressure from the gas phase on a flat, metal substrate (8), and a first particle type forms a matrix with first grains and the second particle type forms grains embedded in the matrix of the metal sliding layer (3), and the metal sliding layer (3) is produced with a thickness (4) of more than 250 m and with a Vickers hardness below 100 HV(0.025), and the metal sliding layer (3) is made of a single layer in only one pass and with a maximum grain size of at most 1 m for at least 90% of the first grains forming the matrix and with a maximum grain size for at least 90% of the embedded grains, and a maximum particle size of at most 1.5 m for the remaining grains making up 100% of all grains.

A hydroelectric turbine may include a stator comprising a first plurality of electricity-generating elements and a rotor comprising a second plurality of electricity-generating elements. The rotor may be disposed radially outward of an outer circumferential surface of the stator and configured to rotate around the stator about an axis of rotation. The rotor may be a flexible belt structure. The turbine may further include at least one bearing mechanism configured to support the rotor relative to the stator during rotation of the rotor around the stator.

A bearing comprising: (a) an inner ring, (b) an outer ring, and (c) a bearing liner disposed therebetween, wherein the bearing liner comprises a resin having a glass transition temperature of less than 150 C.

A bearing comprising (a) an inner ring, (b) an outer ring, and (c) a bearing liner disposed therebetween, wherein the bearing liner comprises a resin and the bearing liner has at least one of: (a) a flexural modulus of from 20 to 35 GPa and (b) a flexural strength of from 500 to 700 MPa.

A sliding member having more improved wear resistance is provided at a low cost. A sliding member is provided with: a substrate which is made of a nonwoven fabric; and a base resin which includes a phenol resin and which is impregnated into the substrate. The nonwoven fabric is preferably a bonded nonwoven fabric which is produced by a thermal bonding method, a binder method or the like and which has a strength that can tolerate the tension applied to the substrate in the step for producing the sliding member. It is preferable that the nonwoven fabric is made of a polyethylene terephthalate (PET) fiber which exhibits a high affinity for the phenol resin. Further, it is preferable that the phenol resin contains a chelating agent which can increase sites of crosslink with hydroxyl groups of the phenol resin.

A sliding member having more improved wear resistance is provided at a low cost. A sliding member is provided with: a substrate which is made of a nonwoven fabric; and a base resin which includes a phenol resin and which is impregnated into the substrate. The nonwoven fabric is preferably a bonded nonwoven fabric which is produced by a thermal bonding method, a binder method or the like and which has a strength that can tolerate the tension applied to the substrate in the step for producing the sliding member. It is preferable that the nonwoven fabric is made of a polyethylene terephthalate (PET) fiber which exhibits a high affinity for the phenol resin. Further, it is preferable that the phenol resin contains a chelating agent which can increase sites of crosslink with hydroxyl groups of the phenol resin.