A lift system includes at least one travel rail mounted in a shaft, and a lift car having a chassis that is disposed on and movable along the travel rail in a travel direction. Also mounted in the shaft is a slotted hollow conductor having a slot defined therein extending in the travel direction. A holding arrangement that holds a cabin antenna extending therefrom is further coupled to, and movable with, the lift car in the travel direction, such that the cabin antenna protrudes into an interior of the slotted hollow conductor through the slot, and is movable along the length of the slot as the car moves in the travel direction. An antenna guide extends parallel to the travel direction of the lift car and is configured to guide the cabin antenna in the slot of the slotted hollow conductor.

An elevator system may include at least one elevator shaft, at least one elevator car that is displaceable in the at least one elevator shaft, and at least one service vehicle configured to receive an elevator car of the elevator system that is located at a stop floor. The elevator car may be displaced into the service vehicle along a direction of extraction perpendicular to a direction of extent of the at least one elevator shaft. Upon receiving the elevator car, the service vehicle may extract the elevator car from the at least one elevator shaft. A rotatable portion of a rail extending in the shaft along which the elevator car travels may be rotatable so as to align with a rail of the service vehicle.

A method for operating, such as commissioning, an elevator, and an elevator are presented herein. The elevator comprises an electric linear motor for moving movable units. The method comprises moving a first movable unit along a linear stator of the electric linear motor in the elevator shaft, and determining at least one characteristic, such as a floor position or an air gap width of the electric linear motor, at a plurality of elevator shaft positions by the first movable unit, such as by a winding, a coil, or a sensor, during the moving. The method further comprises storing the determined at least one characteristic, and controlling moving of at least a second movable unit, such as comprising another of the elevator cars or a second motor unit, by utilizing the stored at least one characteristic.

An elevator system comprising: a plurality of hoistways, each having at least one rail; at least one car moveable along and between the plurality of hoistways and having: a drive assembly operably connected to the car and including two or more wheels engageable to opposing surfaces of the rail of a hoistway along which the car may move, the drive assembly configured to apply an engagement force to the rail to both support the car at the rail and drive the car along the rail; and at least one shuttle moveable transverse to the plurality of hoistways for transferring the car between the hoistways.

An elevator system contains a plurality of cars; a twin channel vertical hoistway, a first channel for ascending movement and a second descending movement; and a plurality of horizontal connecting passages between the twin channel vertical hoistway. Sprocket and wheel system mounted in vertical hoistway move cars vertically. Rotatable disc coupled to levers move cars in horizontal connecting passages. Electrical system coupling motors for vertical hoisways enables energy exchange between ascending and descending cars.

A building shuttle box delivery system includes a plurality of delivery ducts connected in a delivery network. The system further includes a plurality of delivery vehicles configured to travel along the delivery ducts and are accessible via a plurality of access ports distributed along the delivery network. The system may further include hold devices, movement rails, positional pads, directional pads, crawler wheel assemblies and fall brakes disposed on the delivery ducts and delivery vehicles to facilitate travel throughout the delivery network.

The present disclosure relates to a lift system including at least one lift shaft and a plurality of lift cars which can be individually moved. A plurality of the lift cars can be moved in the same lift shaft. The lift system further includes a control system for controlling the lift system. The lift cars of the lift system each have a unique identifier, for example an RFID transponder or a QR code. The disclosure further relates to a method for operating a lift system of this kind.

An elevator system includes first and second intersecting elevator shafts having respective guide devices disposed therein to guide the elevator car. The intersection area of the shafts includes a third guide device that rotates with respect to the shaft walls between alignment with the first and second elevator shafts, to permit an elevator car to transfer from one elevator shaft to the other. A safety device triggers a blocking signal in a control unit to prevent movement of the third guide device if the extent, or footprint/area, of the elevator car spatially overlaps the intersection extent defined by the area over which the third guide device can be rotated in the intersection area. A method for operating the elevator system includes triggering a blocking signal to prevent movement of the third guide device if there is an overlap between the elevator car extent and the intersection extent.

A modular transfer station for a passenger conveyance system including a multiple of modular transfer station modules, each of the multiple of modular transfer station modules includes a static structure. A method of assembling a modular transfer station for a passenger conveyance including assembling a first interface lane alignment module to a second a second modular transfer station parking module, wherein each of the multiple of modular transfer station modules includes a generally equivalent static structure.

A multicar elevator system includes a plurality of elevator sub-systems, each elevator sub-system including a shaft forming a loop path including a first vertical section and a second vertical section connected to each other with at least two horizontal sections. The first vertical section in each elevator sub-system is travelable upwards by at least one elevator car and the second vertical section is travelable downwards by at least one elevator car. The elevator system further include a reservation shaft accessible for at least one elevator car from each elevator subsystem. A method for controlling the multicar elevator system is disclosed.