Provided is a torque sensor that includes: a bearing that is provided with an inner ring and an outer ring that are supported so as to be relatively movable only in the direction of rotation about a predetermined axis; a connecting member that is provided with fixing sections that are respectively fixed to the inner ring and the outer ring and a strain generation section that connects between the fixing sections; and a strain sensor that is disposed on the connecting member so as to be capable of detecting a strain at least in the circumferential direction.

A wind turbine has a drive train that comprises a rotor shaft and a planetary gear train having a first gear stage, the rotor shaft being connected to the planet carrier of the first gear stage in a fixed and backlash-free manner. The rotor shaft is supported, on the side that faces away from the first gear stage, by a toroidal roller bearing, on a first carrying structure. The planet carrier that is connected to the rotor shaft in a fixed and backlash-free manner is supported by a moment bearing, as a fixed bearing. The outer ring of the moment bearing is connected to a housing. The combination of the outer ring of the moment bearing and the housing is connected to a second carrying structure via at least three elastic suspension elements arranged in an annular manner around the rotor axis.

A gas turbine engine comprising a gearbox, the gearbox having gear(s). A journal bearing assembly rotatably supports the gear, the journal bearing assembly having at least a pin, and a journal having a tubular body defining a pin-receiving inner cavity having an inner surface, a first cavity and a second cavity defined in the inner surface of the pin-receiving inner cavity, a rib support located between the first cavity and the second cavity, the rib support being aligned with a longitudinal center of the tubular body, with the first cavity and the second cavity on opposed axial sides of the rib support.

The present invention relates to a method for determining a state of a bearing of a three phase electric machine, the electric machine having a rotor, which is supported by the bearing, the electric machine being connected to a three phase inverter for supplying the electric machine with electric power, the three phase inverter being controlled to apply a pulse width modulation with a predefined scheme to create three phase currents, the method comprises: determining a first phase current provided to the electric machine; determining a second phase current provided to the electric machine, the second phase current being different to the first phase current; determining the power spectral density of the park's vector based on the first phase current and the second phase current; determining an amplitude of the power at a predefined frequency of the power spectral density, wherein the predefined frequency depends on the rotational speed of the rotor and the scheme of the pulse width modulation; comparing the amplitude of the power at the predefined frequency with a predefined power value; anddetermining, based on the comparison, whether a failure of the bearing has occurred or the bearing is degraded.

The present invention relates to a method for determining a state of a bearing of a three phase electric machine, the electric machine having a rotor, which is supported by the bearing, the electric machine being connected to a three phase inverter for supplying the electric machine with electric power, the three phase inverter being controlled to apply a pulse width modulation with a predefined scheme to create three phase currents, the method comprises: determining a first phase current provided to the electric machine; determining a second phase current provided to the electric machine, the second phase current being different to the first phase current; determining the power spectral density of the park's vector based on the first phase current and the second phase current; determining an amplitude of the power at a predefined frequency of the power spectral density, wherein the predefined frequency depends on the rotational speed of the rotor and the scheme of the pulse width modulation; comparing the amplitude of the power at the predefined frequency with a predefined power value; anddetermining, based on the comparison, whether a failure of the bearing has occurred or the bearing is degraded.

A bearing component for rotatably receiving a rotating shaft on an end of a rotating unit includes a component body, an inner protrusion, and one or more outer protrusions. The component body has a recess into which the rotating shaft is rotatably inserted. The inner protrusion protrudes from a wall portion of the recess facing an end surface of the rotating shaft. The inner protrusion receives an axial load by the rotating shaft. The outer protrusions protrude from an outer surface of the component body opposite to the recess. The one or more outer protrusions are in contact with a holding unit. A contact portion between the outer protrusions and the holding unit is offset from a contact portion position between the inner protrusion and the end surface. The contact portion between at least one of the outer protrusions and the holding unit has a non-planar shape.

A sliding member includes a back-metal layer including an Fe alloy and a sliding layer including a copper alloy including 0.5 to 12 mass % of Sn and the balance of Cu and inevitable impurities. The sliding layer has a cross-sectional structure perpendicular to a sliding surface of the sliding layer. The cross-sectional structure includes first copper alloy grains that are in contact with a bonding surface of the back-metal layer and second copper alloy grains that are not in contact with the bonding surface. The first copper alloy grains has an average grain size D1 and the second copper alloy grains has an average grain size D2. D1 and D2 satisfy the following relations: D1 is 30 to 80 m; and D1/D2=0.1 to 0.3.

A support for rotationally movable mounting of solar modules configures an outer shaft as a tube and mounts an inner shaft in it, by way of a calotte element in the end position, so that this element is accommodated in the outer shaft in longitudinally displaceable and tiltable manner, as well as in freely rotational manner, if necessary. In this way, only one roller block is required, even if two uncoupled connection shafts are to be mounted.

A support for rotationally movable mounting of solar modules configures an outer shaft as a tube and mounts an inner shaft in it, by way of a calotte element in the end position, so that this element is accommodated in the outer shaft in longitudinally displaceable and tiltable manner, as well as in freely rotational manner, if necessary. In this way, only one roller block is required, even if two uncoupled connection shafts are to be mounted.

A method for operating a bearing (10), in particular roller bearing or sliding bearing or linear bearing, with at least a first energy supply module (1, 2, 3, 4) and a second energy supply module (1, 2, 3, 4), wherein a first control unit of the first energy supply module (1, 2, 3, 4) and a second control unit of the second energy supply module (1, 2, 3, 4) are configured to control outputting of energy of the respective energy supply module (1, 2, 3, 4) according to a predefined supply strategy, wherein the first control unit and/or the second control unit receive/receives a supply request and controls the outputting of energy by the respective energy supply module (1, 2, 3, 4) as a function of the supply request and the predefined supply strategy.