A road bearing for inductive coupling to an electrical connection device of an electric vehicle includes a series of primary induction coils, a bearing surface element, and a plurality of deformation features in the bearing surface element. The series of primary induction coils are interconnected to a source of electrical power and disposed in a substantially linear array below a roadway surface and within a roadway structure, and are aligned generally parallel to an alignment of the roadway. The bearing surface element is disposed above the primary induction coils, and has an upper surface that is substantially flush with the roadway surface, has a surface flatness in the range of ±1 μm per 30 mm, and a magnetic permeability in the range of 0.9 to 2. The plurality of deformation features include depressions in the upper surface of the bearing surface element, and are configured to provide friction to vehicle wheels.

A road bearing for inductive coupling to an electrical connection device of an electric vehicle includes a series of primary induction coils, a bearing surface element, and a plurality of deformation features in the bearing surface element. The series of primary induction coils are interconnected to a source of electrical power and disposed in a substantially linear array below a roadway surface and within a roadway structure, and are aligned generally parallel to an alignment of the roadway. The bearing surface element is disposed above the primary induction coils, and has an upper surface that is substantially flush with the roadway surface, has a surface flatness in the range of ±1 μm per 30 mm, and a magnetic permeability in the range of 0.9 to 2. The plurality of deformation features include depressions in the upper surface of the bearing surface element, and are configured to provide friction to vehicle wheels.

A conductor line for supplying an electric load movable on the conductor line in the longitudinal direction of the conductor line, includes at least one conductor strand which runs in the longitudinal direction and has an electrically conductive profiled conductor section for contacting a sliding contact of a current collector of the load and at least one elongated slotted waveguide, which runs in the longitudinal direction, with a longitudinal slot for receiving an antenna which can be moved together with the load. A related current collector and a conductor line system are also provided. The aim is to allow a compact and material-saving design with good fault-tolerant transmission. This is achieved by a conductor line in which the longitudinal slot is tilted by an angle which does not equal 90° about the longitudinal direction with respect to a movement plane on which the current collector can be moved, by a current collector in which the antenna or a part thereof is completely or partly tilted by an angle which also does not equal 90° about the longitudinal direction with respect to the movement plane, and by a conductor line system including such a conductor line and current collector.

A conductor line for supplying an electric load movable on the conductor line in the longitudinal direction of the conductor line, includes at least one conductor strand which runs in the longitudinal direction and has an electrically conductive profiled conductor section for contacting a sliding contact of a current collector of the load and at least one elongated slotted waveguide, which runs in the longitudinal direction, with a longitudinal slot for receiving an antenna which can be moved together with the load. A related current collector and a conductor line system are also provided. The aim is to allow a compact and material-saving design with good fault-tolerant transmission. This is achieved by a conductor line in which the longitudinal slot is tilted by an angle which does not equal 90° about the longitudinal direction with respect to a movement plane on which the current collector can be moved, by a current collector in which the antenna or a part thereof is completely or partly tilted by an angle which also does not equal 90° about the longitudinal direction with respect to the movement plane, and by a conductor line system including such a conductor line and current collector.

The invention relates to a rack storage system comprising a storage rack (1) with storage shelves (12a, 12b) having storage spaces (17) for articles in rack stages (16) lying one above the other with a rack aisle (15) extending in between. Several guide tracks with first and second guide rails run along the rack aisle (15) (27, 28). First and second conveyor vehicles (3a, 3b) can be moved on the guide tracks, each of the conveyor vehicles (3a, 3b) having a drive motor (65a, 65b) and an electronic control unit (66a, 66b) and being controllable independently of one another. The first guide rail (27) is equipped with a first contact line arrangement (67) and the second guide rail (28) is equipped with a second contact line arrangement (68), each of the contact line arrangements (67, 68) comprising dedicated contact lines (69, 70). For energy and/or data supplying purposes, current collectors (71a) of the first conveyor vehicle (3a) contact the contact lines (69) of the first contact line arrangement (67) and current collectors (71b) of the second conveyor vehicle (3b) contact the contact lines (70) of the second contact line arrangement (68). The first conveyor vehicle (3a) and the second conveyor vehicle (3b) can be moved simultaneously and independently of one another on the same conveying track.

The invention relates to a rack storage system comprising a storage rack (1) with storage shelves (12a, 12b) having storage spaces (17) for articles in rack stages (16) lying one above the other with a rack aisle (15) extending in between. Several guide tracks with first and second guide rails run along the rack aisle (15) (27, 28). First and second conveyor vehicles (3a, 3b) can be moved on the guide tracks, each of the conveyor vehicles (3a, 3b) having a drive motor (65a, 65b) and an electronic control unit (66a, 66b) and being controllable independently of one another. The first guide rail (27) is equipped with a first contact line arrangement (67) and the second guide rail (28) is equipped with a second contact line arrangement (68), each of the contact line arrangements (67, 68) comprising dedicated contact lines (69, 70). For energy and/or data supplying purposes, current collectors (71a) of the first conveyor vehicle (3a) contact the contact lines (69) of the first contact line arrangement (67) and current collectors (71b) of the second conveyor vehicle (3b) contact the contact lines (70) of the second contact line arrangement (68). The first conveyor vehicle (3a) and the second conveyor vehicle (3b) can be moved simultaneously and independently of one another on the same conveying track.

An overhead type transport apparatus includes: a guide rail that includes a main rail and one or more sub rails crossing the main rail and is fixed to a ceiling side; two or more transport units that travel along the guide rail; a carrier unit that is coupled to the bottom of each transport unit and rotates about a carrier rotating unit, one end being inclined upward or downward with respect to the other end; and a basket unit that is attached to and detached from the bottom of each carrier unit.

A charging system for an electric vehicle has an elongate enclosure having a plurality of sides and an at least partially open side. The enclosure defines a hollow interior. The charging system further includes a conductor rail disposed in the hollow interior and that is accessible through the at least partially open side of the enclosure. The conductor rail may be placed in electric communication with an electrical power source and thereby may be selectively placed in electrical communication with an electrical connector of an electric vehicle. The charging system may conduct electric current from the electrical power source to an electric power supply of the electric vehicle.

A wear indicator system may include a switch assembly having a housing, a wear indicator circuit, and an actuator assembly. The housing may connect to a collector shoe assembly having a collector shoe that slides in contact along a conductor bar of a conductor bar assembly, for transferring electrical power between the collector shoe and the conductor bar. The wear indicator circuit may include a communication unit and a switch unit. The actuator assembly may be operably coupled to the housing and to the switch unit and may track along the conductor bar assembly when the collector shoe assembly moves and may contact the conductor bar assembly to depress to a position to activate the switch unit responsive to the collector shoe reaching a designated wear level. The communication unit may communicate a signal indicative of the designated wear level responsive to the switch unit being activated.

An apparatus for transmission of electricity by conduction to a vehicle while in motion.