A method for propelling of a vehicle comprising a power train with an electric motor connected to a location in the vehicle intended for mounting of an energy supply unit intended for driving of the electric motor during normal operating conditions of the vehicle is described. The method comprises the steps of: connecting an electric power source to a power connection element mounted on the vehicle and being connected to the electric motor and to the location, disconnecting the location in order to accomplish a direct connection between the power connection element and the electric motor and propelling the vehicle by means of the electric motor powered by electricity from the electric power source. A method for manufacturing of a vehicle comprising a power train with an electric motor and a vehicle comprising a power train with an electric motor are also described herein.

A method for propelling of a vehicle comprising a power train with an electric motor connected to a location in the vehicle intended for mounting of an energy supply unit intended for driving of the electric motor during normal operating conditions of the vehicle is described. The method comprises the steps of: connecting an electric power source to a power connection element mounted on the vehicle and being connected to the electric motor and to the location, disconnecting the location in order to accomplish a direct connection between the power connection element and the electric motor and propelling the vehicle by means of the electric motor powered by electricity from the electric power source. A method for manufacturing of a vehicle comprising a power train with an electric motor and a vehicle comprising a power train with an electric motor are also described herein.

Provided is a running device including a frame (11) and a first wheel part (15) and a second wheel part (35) arranged with an appropriate distance therebetween along a running direction (R). The first wheel part (15) includes a first left support arm (17) and a first right support arm (26) arranged on the frame (11) in a manner to be swingable within a plane extending along the running direction (R). The second wheel part (35) includes a second support arm (36) arranged on the frame (11) in a manner to be swingable within a plane perpendicular to the running direction (R). The first left support arm (17) has first left wheels (19, 21) respectively on both sides thereof, and the first right support arm (26) has first right wheels (28, 30) respectively on both sides thereof. The second support arm (36) has a second left wheel (38) and a second right wheel (40) respectively on both sides thereof.

Provided is a running device including a frame (11) and a first wheel part (15) and a second wheel part (35) arranged with an appropriate distance therebetween along a running direction (R). The first wheel part (15) includes a first left support arm (17) and a first right support arm (26) arranged on the frame (11) in a manner to be swingable within a plane extending along the running direction (R). The second wheel part (35) includes a second support arm (36) arranged on the frame (11) in a manner to be swingable within a plane perpendicular to the running direction (R). The first left support arm (17) has first left wheels (19, 21) respectively on both sides thereof, and the first right support arm (26) has first right wheels (28, 30) respectively on both sides thereof. The second support arm (36) has a second left wheel (38) and a second right wheel (40) respectively on both sides thereof.

Techniques for conveyor systems that integrate robotic smart carrier nests whose configurations are dynamically changed based on product geometry are provided. In one embodiment, a system can include a modular nest configured to hold product during assembly. The modular nest includes a first actuator comprising a first pair of gripping arms that open and close in a first direction based on a first signal. The modular nest also includes a second actuator comprising a second pair of gripping arms that open and close in a second direction based on a second signal. The first signal and the second signal are based on a geometry of the product. Further, the first direction and the second direction are different directions.

The vehicle body assembly station comprises main transport assembly for conveying a vehicle body along a first direction D1 in which at least one assembly robot is provided to move along a second direction D2, and temporary transport assembly whose operation is more accurate than that of the main transport assembly for moving the vehicle body independently from the main transport assembly while the assembly robot is performing operations on the vehicle body, whereby a new coordinate reference system is created by the temporary transport assembly.

The vehicle body assembly station comprises main transport assembly for conveying a vehicle body along a first direction D1 in which at least one assembly robot is provided to move along a second direction D2, and temporary transport assembly whose operation is more accurate than that of the main transport assembly for moving the vehicle body independently from the main transport assembly while the assembly robot is performing operations on the vehicle body, whereby a new coordinate reference system is created by the temporary transport assembly.

A conveying system for simultaneously transporting workpieces and workers having a plurality of vehicles, which each have a workpiece receptacle, an assembly platform for workers to move around on, and a separate drive, with which each vehicle can be driven independently of other vehicles of the conveying system. Furthermore, the conveying system includes a plurality of workstations, which are set up for carrying out different work steps. A control device is configured to control the vehicles such that they can pass individually through a different succession of workstations depending on the transported workpiece.

A conveying system for simultaneously transporting workpieces and workers having a plurality of vehicles, which each have a workpiece receptacle, an assembly platform for workers to move around on, and a separate drive, with which each vehicle can be driven independently of other vehicles of the conveying system. Furthermore, the conveying system includes a plurality of workstations, which are set up for carrying out different work steps. A control device is configured to control the vehicles such that they can pass individually through a different succession of workstations depending on the transported workpiece.

A transport system for transporting workpieces includes a plurality of objects disposed along a path of travel and a driverless transport vehicle having a workpiece holder and a personal protection sensor such as a laser scanner. The sensor has a transmitter for generating detection radiation and a receiver adapted to receive detection radiation generated by the transmitter and reflected from persons or objects located in a monitoring area that is monitored by the detection radiation. A control device steers the transport vehicle along the travel path so that it does not collide with the objects and triggers a safety measure if the personal protection sensor has detected a person in the monitoring area. The objects support a coating or cladding that absorbs detection radiation impinging thereon or reflects it in such a direction that it cannot reach the receiver. As a result, the objects become invisible to the personal protection sensor and cannot trigger any safety measures.