A system for moving loads, in particular within an aircraft, comprising: a cargo hold floor, at least one row of rollers including a plurality of rollers integrated into the floor one behind another, at least one guide rail in the floor extending substantially parallel to the row of rollers, and at least one transport vehicle removably received in and movable along the guide rail. At least one coupling arrangement selectively couples the vehicle with a load arranged on the row of rollers, the load being movable with the vehicle. At least one locking arrangement, in an active state, locking the load relative to the floor and, in a non-active state, allowing a relative movement between the load and the floor. The vehicle operates the locking arrangement according to at least one of the following: so that it assumes the active state; and, so that it assumes the non-active state.

Provided is a driving force transmission device including: an actuator (22) that, in a case where one of a first annular gear (11), a second annular gear (14), and a carrier (16) is an input member, another one is an output member, and the remaining one is a rotational member, causes one of the input member and the output member to rotate integrally with the rotational member. When driving force is inputted from the drive source to the input member and input member is rotated unidirectionally, the rotation direction of the output member in the case where one of the input member and the output member rotates integrally with the rotational member is reversed with respect to that in a case where one of the input member and the output member does not rotate integrally with the rotational member.

Provided is a driving force transmission device including: an actuator (22) that, in a case where one of a first annular gear (11), a second annular gear (14), and a carrier (16) is an input member, another one is an output member, and the remaining one is a rotational member, causes one of the input member and the output member to rotate integrally with the rotational member. When driving force is inputted from the drive source to the input member and input member is rotated unidirectionally, the rotation direction of the output member in the case where one of the input member and the output member rotates integrally with the rotational member is reversed with respect to that in a case where one of the input member and the output member does not rotate integrally with the rotational member.

A prognostic power drive unit of a cargo handling system includes a motor operable to drive a conveyor system of the cargo handling system. One or more drive system sensors are operable to collect data related to the motor. One or more environmental sensors are operable to collect data related to one or more environmental conditions of the prognostic power drive unit. One or more load detection sensors are operable to detect data related to the conveyor system. The prognostic power drive unit also includes a controller operable to control the motor and determine a health status of the cargo handling system based on at least one of: the one or more drive system sensors, the one or more environmental sensors, and the one or more load detection sensors.

A prognostic power drive unit of a cargo handling system includes a motor operable to drive a conveyor system of the cargo handling system. One or more drive system sensors are operable to collect data related to the motor. One or more environmental sensors are operable to collect data related to one or more environmental conditions of the prognostic power drive unit. One or more load detection sensors are operable to detect data related to the conveyor system. The prognostic power drive unit also includes a controller operable to control the motor and determine a health status of the cargo handling system based on at least one of: the one or more drive system sensors, the one or more environmental sensors, and the one or more load detection sensors.

It is disclosed: a conveying system; an interface station; as well as a method for transferring a conveying good from a driverless transport vehicle (DTV) via an interface station, which includes a diverting conveyor unit, to a continuous conveyor operated at a preset conveying speed and comprising a preferred conveying direction, wherein the method comprises the steps of: actuatorless inertia-based delivering the conveying good from the DTV to the interface station; repeatedly detecting, by a sensor system, the delivered conveying good in an area of the interface station, while the delivered conveying good moves due to the inertia-based delivery, and generating corresponding sensor signals; based on the sensor signals, determining, by a controlling unit, a current speed and movement direction of the delivered conveying good; based on the current speed and movement direction, generating, by the controlling unit, a current control signal for the diverting conveyor unit such that the current speed and movement direction of the delivered conveying good are, at the latest at the time of transition of the delivered conveying good from the interface station onto the continuous conveyor, identical to the preset conveying speed and the preferred conveying direction of the continuous conveyor; and influencing a current movement of the conveying good by the diverting conveyor unit in accordance with the current control signal received by the diverting conveyor unit from the controlling unit.

Apparatuses, methods, and systems comprising reconfigurable motorized conveyor rollers are provided. The example reconfigurable motorized conveyor roller includes a housing with a first end and a second end opposite to the first end. The housing includes a plurality of curved plates that at least partially form a cylindrical tube. The reconfigurable motorized conveyor roller includes a motor assembly and a drive assembly at least partially disposed within the housing that are configured to cause rotation of at least a portion of the reconfigurable motorized conveyor roller. And, the reconfigurable motorized conveyor roller includes a housing adjustment assembly disposed within the housing that is operable to modify one or more dimensions of the housing.

A lift roller may include a hub having a first surface, a second surface opposite the first surface, and a radially outward surface. The hub may define a channel extending through the hub from the first surface to the second surface. The lift roller may also include a rim portion rotatably disposed about the radially outward surface of the hub and a boss disposed on one of the first surface and the second surface.

Disclosed is a friction conveying system, comprising a friction driving unit, a clamping unit and a friction driving component, wherein the friction driving unit comprises a rotation driving component, a first connecting rod, a second connecting rod, at least one first rollers arranged on the first connecting rod, and at least one second rollers arranged on the second connecting rod, the clamping unit comprises a clamping driving component by which the first connecting rod and the second connecting rod are moved towards each other to cause the first rollers and the second rollers to clamp the friction driving component, the first rollers and/or the second rollers are drivable by the rotation driving component to rotate, causing the friction driving component clamped between the first rollers and the second rollers to move by means of frictional force. According to the invention, the rollers are used to drive the friction driving component to move at a high speed by means of frictional force, providing high-speed conveyance at lower cost. The present invention has the advantages of lower cost, reliable performance, and convenient mounting, satisfying the conveying requirements of industrial automatic production line.

Disclosed is a friction conveying system, comprising a friction driving unit, a clamping unit and a friction driving component, wherein the friction driving unit comprises a rotation driving component, a first connecting rod, a second connecting rod, at least one first rollers arranged on the first connecting rod, and at least one second rollers arranged on the second connecting rod, the clamping unit comprises a clamping driving component by which the first connecting rod and the second connecting rod are moved towards each other to cause the first rollers and the second rollers to clamp the friction driving component, the first rollers and/or the second rollers are drivable by the rotation driving component to rotate, causing the friction driving component clamped between the first rollers and the second rollers to move by means of frictional force. According to the invention, the rollers are used to drive the friction driving component to move at a high speed by means of frictional force, providing high-speed conveyance at lower cost. The present invention has the advantages of lower cost, reliable performance, and convenient mounting, satisfying the conveying requirements of industrial automatic production line.