A sawtooth station comprising a passenger waiting area; an autonomous vehicle area sized to allow autonomous vehicles to simultaneously travel in opposite directions of travel and turn around; and one or more sawtooth berths separating the passenger waiting area from the autonomous vehicle area, whereby autonomous vehicles traveling in in opposite directions use the one or more sawtooth births and the autonomous vehicles furthest from the one or more sawtooth berths can turn around in the autonomous vehicle area in order to stop at the one or more sawtooth berths.

A sawtooth station comprising a passenger waiting area; an autonomous vehicle area sized to allow autonomous vehicles to simultaneously travel in opposite directions of travel and turn around; and one or more sawtooth berths separating the passenger waiting area from the autonomous vehicle area, whereby autonomous vehicles traveling in in opposite directions use the one or more sawtooth births and the autonomous vehicles furthest from the one or more sawtooth berths can turn around in the autonomous vehicle area in order to stop at the one or more sawtooth berths.

The invention relates to a vehicle (1) for transporting people on a sloping track (V) of a cable transport installation, said vehicle comprising a carriage (10) suitable for running on the track (V) while being drawn by at least one traction cable (C1) of the transport installation, a cabin support (120) carried by the carriage (10), an onboard braking device (14) and a shock absorber (13) linked to the onboard braking device and to the cabin support (120), and suitable for transforming the kinetic energy of the cabin support (120) into heat when the cabin support (120) moves relative to the onboard braking device (14) along a shock absorption trajectory in the shock absorption direction, characterized in that the onboard braking device (14) is rigidly connected to the carriage (10) and the vehicle also comprises a slide link (12) between the cabin support (120) and the carriage (10) to guide a movement of the cabin support (120) relative to the carriage (10) along the shock absorption trajectory.

The invention relates to a vehicle (1) for transporting people on a sloping track (V) of a cable transport installation, said vehicle comprising a carriage (10) suitable for running on the track (V) while being drawn by at least one traction cable (C1) of the transport installation, a cabin support (120) carried by the carriage (10), an onboard braking device (14) and a shock absorber (13) linked to the onboard braking device and to the cabin support (120), and suitable for transforming the kinetic energy of the cabin support (120) into heat when the cabin support (120) moves relative to the onboard braking device (14) along a shock absorption trajectory in the shock absorption direction, characterized in that the onboard braking device (14) is rigidly connected to the carriage (10) and the vehicle also comprises a slide link (12) between the cabin support (120) and the carriage (10) to guide a movement of the cabin support (120) relative to the carriage (10) along the shock absorption trajectory.

A transport carriage for transporting workpieces, the transport carriage being movable on a mounting rail in a transport direction. The transport carriage has a transport carriage chassis which supports at least one drive roller that can roll on a drive running surface of the mounting rail and can be driven by a drive motor, the drive motor being carried along with the transport carriage chassis. The transport carriage additionally includes at least one securing device for at least one workpiece. The transport carriage carries along an autonomous power supply device which can supply the drive motor with power. A system is additionally provided for transporting workpieces, having a rail system which has at least one mounting rail and includes at least one such transport carriage which can be moved on the mounting rail in a transport direction.

A transport carriage for transporting workpieces, the transport carriage being movable on a mounting rail in a transport direction. The transport carriage has a transport carriage chassis which supports at least one drive roller that can roll on a drive running surface of the mounting rail and can be driven by a drive motor, the drive motor being carried along with the transport carriage chassis. The transport carriage additionally includes at least one securing device for at least one workpiece. The transport carriage carries along an autonomous power supply device which can supply the drive motor with power. A system is additionally provided for transporting workpieces, having a rail system which has at least one mounting rail and includes at least one such transport carriage which can be moved on the mounting rail in a transport direction.

A trolley 100 for a rail 10 is described. The trolley 100 comprises a frame 110, a set S of wheels 120, including a first wheel 120A and a second wheel 120B, rotatably coupled to the frame 110 and an attachment member 130, coupled to the frame 110, for suspension of a load W therefrom, in use. The first wheel 120A is rotatable in a first plane P1 about a first axis A1 and the second wheel 120B is rotatable in a second plane P2 about a second axis A2. The first plane P1 and the second plane P2 define a line L. The trolley 100 is arrangeable in a first configuration, wherein the attachment member 130 is arranged at a first angular displacement D1 about the line L. The trolley 100 is arrangeable in a second configuration, wherein the attachment member 130 is arranged at a second angular displacement D2 about the line L, wherein the first angular displacement D1 and the second angular displacement D2 are different. A rail assembly 1, including the trolley 100 and the rail 10, is also described.

A trolley 100 for a rail 10 is described. The trolley 100 comprises a frame 110, a set S of wheels 120, including a first wheel 120A and a second wheel 120B, rotatably coupled to the frame 110 and an attachment member 130, coupled to the frame 110, for suspension of a load W therefrom, in use. The first wheel 120A is rotatable in a first plane P1 about a first axis A1 and the second wheel 120B is rotatable in a second plane P2 about a second axis A2. The first plane P1 and the second plane P2 define a line L. The trolley 100 is arrangeable in a first configuration, wherein the attachment member 130 is arranged at a first angular displacement D1 about the line L. The trolley 100 is arrangeable in a second configuration, wherein the attachment member 130 is arranged at a second angular displacement D2 about the line L, wherein the first angular displacement D1 and the second angular displacement D2 are different. A rail assembly 1, including the trolley 100 and the rail 10, is also described.

A device includes an EMG processing application operable with a processing module to receive an output signal from EMG testing, wherein the output signal represents electrical activity of at least one muscle. The EMG processing application is operable to process the output signal to detect at least one type of waveform of a plurality of types of waveforms from the output signal and display the detected at least one type of waveform.

The invention relates to a vehicle (1) for transporting people on a sloping track (V) of a cable transport installation, said vehicle comprising a carriage (10) suitable for running on the track (V) while being drawn by at least one traction cable (C1) of the transport installation, a cabin support (120) carried by the carriage (10), an onboard braking device (14) and a shock absorber (13) linked to the onboard braking device and to the cabin support (120), and suitable for transforming the kinetic energy of the cabin support (120) into heat when the cabin support (120) moves relative to the onboard braking device (14) along a shock absorption trajectory in the shock absorption direction, characterized in that the onboard braking device (14) is rigidly connected to the carriage (10) and the vehicle also comprises a slide link (12) between the cabin support (120) and the carriage (10) to guide a movement of the cabin support (120) relative to the carriage (10) along the shock absorption trajectory.