A rim-type abrasion cutter drive sprocket (24) for driving an abrasion cutting chain (16) of an abrasion cutter (10) comprises a set of sprocket teeth, which extend radially away from the drive sprocket's rotation axis (A), and define drive link gaps between them for receiving and drivingly engaging with drive links (26) of the cutting chain (16), and a pair of rim edges (44) which are concentric with and extend about the rotation axis (A) on either side of the drive link gaps, the rim edges (44) being configured to radially support side links (28) of the cutting chain (16). The rim edges (44) have a non-circular envelope, as seen along the rotation axis (A).

A drive sprocket can include a plurality of teeth for meshing with a drive member to transmit rotary motion. The drive member can include a plurality of engagement pockets engaging the teeth of the drive sprocket, where each tooth has a tooth profile defined by a first side comprising a first engagement surface and an opposite second side comprising a second engagement surface, which engagement surfaces are configured such that when driven, a tooth meshes to the engagement pocket at a first contact location on the first engagement surface and also at a second contact location on the second engagement surface.

A drive sprocket can include a plurality of teeth for meshing with a drive member to transmit rotary motion. The drive member can include a plurality of engagement pockets engaging the teeth of the drive sprocket, where each tooth has a tooth profile defined by a first side comprising a first engagement surface and an opposite second side comprising a second engagement surface, which engagement surfaces are configured such that when driven, a tooth meshes to the engagement pocket at a first contact location on the first engagement surface and also at a second contact location on the second engagement surface.

A chain for a bicycle, a sprocket cassette, a chainring, a crankset, a chain drive system, and a bicycle are provided. The chain comprises a plurality of interleaved link elements, each link element being pivotably attached to at least one other link element and comprising at least two teeth. A flank of each tooth is adapted to engage with a flank of a sprocket tooth. The sprocket cassette comprises one or more sprockets, each comprising a plurality of sprocket teeth, wherein each sprocket tooth has a flank with a profile corresponding to a profile of at least part of a tooth of each of the plurality of link elements. The chainring comprises a plurality of sprocket drive teeth having a profile corresponding to the profile of at least one of the teeth of each of the plurality of link elements.

A dual motor electric drive axle apparatus is disclosed that is enclosed within a single housing. First and second motors are disposed in the housing. First and second rotor shafts, and first and second chain drives including first and second driving sprockets are connected to the first rotor shaft. A first chain, and a first driven sprocket are connected to the first and second driving shafts by first and second chain respectively. First and second planetary gear sets having first and second input shafts are connected to the first and second driven sprockets. First and second output shafts are connected to first and second constant velocity joints that are located outside the housing. First and second axles are connected to the first and second constant velocity joints and are adapted to rotate first and second wheels respectively.

A fan apparatus may include a frame, a fan, and a drive mechanism. The fan may be supported for rotation relative to the frame and may include a fan shaft and a plurality of blades extending outward from the fan shaft. The drive mechanism may include a driven wheel, a drive shaft, a first drive wheel, a second drive wheel, and a torque-transmission loop. The driven wheel may be mounted on the fan shaft. The drive shaft may be supported for rotation relative to the frame. The first drive wheel may be mounted on the drive shaft. The second drive wheel may be mounted on the drive shaft. The torque-transmission loop may be engaged with the driven wheel and a selected one of the first and second drive wheels.

A fan apparatus may include a frame, a fan, and a drive mechanism. The fan may be supported for rotation relative to the frame and may include a fan shaft and a plurality of blades extending outward from the fan shaft. The drive mechanism may include a driven wheel, a drive shaft, a first drive wheel, a second drive wheel, and a torque-transmission loop. The driven wheel may be mounted on the fan shaft. The drive shaft may be supported for rotation relative to the frame. The first drive wheel may be mounted on the drive shaft. The second drive wheel may be mounted on the drive shaft. The torque-transmission loop may be engaged with the driven wheel and a selected one of the first and second drive wheels.

There is presented various embodiments disclosed in this application, including an improved crankshaft system using a load connecting member which provides a greater maximum torque angle than a conventional system, thereby improving efficiency and power.

A power transmission device includes a first input shaft configured to input power from a first power source, a second input shaft configured to input power from a second power source, a first output shaft configured to transmit power to a first drive wheel, a second output shaft configured to transmit power to a second drive wheel, and a differential gear including, as three rotation elements, a first rotation element to which the second input shaft is connected, a second rotation element to which the second output shaft is connected, and a third rotation element to which the first input shaft and the first output shaft are connected, in which an engagement device configured to selectively connect any two of the three rotation elements is provided.

A power transmission device includes a first input shaft configured to input power from a first power source, a second input shaft configured to input power from a second power source, a first output shaft configured to transmit power to a first drive wheel, a second output shaft configured to transmit power to a second drive wheel, and a differential gear including, as three rotation elements, a first rotation element to which the second input shaft is connected, a second rotation element to which the second output shaft is connected, and a third rotation element to which the first input shaft and the first output shaft are connected, in which an engagement device configured to selectively connect any two of the three rotation elements is provided.