A power converter includes a chassis having attached thereto a holding fixture for mounting the chassis to a mounting portion in a suspended manner. The holding fixture includes a first member attached to a first surface of the chassis which faces the mounting portion, and a second member attached to the first member and a second surface of the chassis that adjoins the first surface.

A power converter to be mounted to a mounting portion of a host in a suspended manner includes a plurality of component-housing chassis configured to be connected together parallel to the mounting portion, the plurality of component-housing chassis each containing parts for a power converter so that the plurality of component-housing chassis collectively constitute the power converter for the host, wherein at least one of the plurality of component-housing chassis has a support frame, the support frame protruding out so as to extend into at least an adjacent one of the component-housing chassis, wherein the at least adjacent one of the component-housing chassis has an insertion hole for inserting the support frame, and wherein the support frame is configured to be inserted into the insertion hole in the adjacent component-housing chassis and fixed to the adjacent component-housing chassis.

A power converter to be mounted to a mounting portion of a host in a suspended manner includes a plurality of component-housing chassis configured to be connected together parallel to the mounting portion, the plurality of component-housing chassis each containing parts for a power converter so that the plurality of component-housing chassis collectively constitute the power converter for the host, wherein at least one of the plurality of component-housing chassis has a support frame, the support frame protruding out so as to extend into at least an adjacent one of the component-housing chassis, wherein the at least adjacent one of the component-housing chassis has an insertion hole for inserting the support frame, and wherein the support frame is configured to be inserted into the insertion hole in the adjacent component-housing chassis and fixed to the adjacent component-housing chassis.

A fastening clamp for holding objects on a profiled support reliably secures the objects to the profiled support for extended periods of time. The clamp has two clamping brackets which are disposed opposite to each other in a clamping direction and delimit a clamping gap configured to receive a leg of the profiled support. At least one connection web is rigidly connected to the clamping brackets, a clamp element pressing device is connected to the clamping brackets and configured to generate a clamping force in the clamping direction, a transverse clamping unit is fastened to the clamping brackets or to one of the connection webs and has a clamping tongue configured to reach behind the profiled support, and a clamping tongue contact pressure device is connected to the transverse clamping unit and configured to apply a transverse clamping force to the clamping tongue.

A vehicle control facility for the automated control of an electrical road vehicle for a route system with an energy-supply system that includes a lane-bound energy supply line, in particular an overhead line system. A position-determining unit determines a geographical position of the electrical road vehicle. A specific-lane-determining unit determines position data for a specific lane assigned to the lane-bound energy supply line. A communication interface transmits current relative positions of infrastructure features with respect to the electrical road vehicle to an external central specific-lane-determining facility and receives position data. A vehicle-control unit controls the electrical road vehicle with respect to the determined specific lane in dependence on the determined relative position of the specific lane.

A vehicle control facility for the automated control of an electrical road vehicle for a route system with an energy-supply system that includes a lane-bound energy supply line, in particular an overhead line system. A position-determining unit determines a geographical position of the electrical road vehicle. A specific-lane-determining unit determines position data for a specific lane assigned to the lane-bound energy supply line. A communication interface transmits current relative positions of infrastructure features with respect to the electrical road vehicle to an external central specific-lane-determining facility and receives position data. A vehicle-control unit controls the electrical road vehicle with respect to the determined specific lane in dependence on the determined relative position of the specific lane.

A pantograph configuration for a vehicle has at least one pantograph embodied for at least temporary contact with an electrical network located externally outside the vehicle. The pantograph is movable from a contact position into a rest position. A first electrical network is located internally within the vehicle, which in the contact position is connected to the pantograph. A second electrical network located internally within the vehicle is connected to a ground or mass potential of the vehicle and in the rest position to the pantograph. In order to ensure that the pantograph is voltage-free in the rest position, the pantograph is connected to the first electrical network and the second electrical network in the rest position.

A pantograph configuration for a vehicle has at least one pantograph embodied for at least temporary contact with an electrical network located externally outside the vehicle. The pantograph is movable from a contact position into a rest position. A first electrical network is located internally within the vehicle, which in the contact position is connected to the pantograph. A second electrical network located internally within the vehicle is connected to a ground or mass potential of the vehicle and in the rest position to the pantograph. In order to ensure that the pantograph is voltage-free in the rest position, the pantograph is connected to the first electrical network and the second electrical network in the rest position.

A vehicle is provided that connects to an power structure for powering and guiding the vehicle. The power structure includes a trolley, a track along which the trolley runs, a power source connected to the track, and a cable connected to the trolley and configured to attach to the vehicle moving on a surface. The vehicle includes a chassis and a cable connected to the chassis and configured to mechanically and electrically connect the vehicle to the power structure. The chassis includes a connector rotatable 360 degrees, and the cable connects to the chassis through the connector.

A vehicle is provided that connects to an power structure for powering and guiding the vehicle. The power structure includes a trolley, a track along which the trolley runs, a power source connected to the track, and a cable connected to the trolley and configured to attach to the vehicle moving on a surface. The vehicle includes a chassis and a cable connected to the chassis and configured to mechanically and electrically connect the vehicle to the power structure. The chassis includes a connector rotatable 360 degrees, and the cable connects to the chassis through the connector.