Abstract: A method for maintaining an elevator installation includes performing at least one maintenance step that includes interacting with an elevator control of the elevator installation. The method further comprises confirming by the elevator control a performance of the maintenance step based on the at least one interaction. An elevator control for an elevator installation includes at least one maintenance step and an interaction signature associated with the maintenance step stored therein. An elevator installation includes an elevator control having at least one maintenance step and an interaction signature associated with the maintenance step stored therein.

Abstract: A method can be used to position a car door and a landing-stop door in a synchronized manner at a landing stop in an elevator shaft of an elevator system. The car door may be configured as a guide door, and the landing-stop door may be configured as a follower door. The method may involve bringing an elevator car close to the landing stop, upon entry of the car door into an unlock zone sensing a presence signal of the follower door by way of a presence sensor of the guide door, actuating the guide-door drive by way of the guide controller and executing an opening movement of the guide door, providing movement information of the guide door, and actuating the follower-door drive of the follower door.

Abstract: A drive arrangement includes a movable, rotatable rail segment of an elevator system. An electric motor moves the movable rail segment. The drive arrangement is configured to rotate the rail segment about an angle of rotation of less than 360°. An inverter unit provides electrical power to the electric motor and is configured to receive a control command relating to the position of the movable rail segment and provide the electrical drive power based on the control command. The drive arrangement forms two or exactly three drive segments. Each drive segment includes an inverter unit and a coil arrangement, which is supplied with electrical power by the assigned inverter unit. Each inverter unit includes a communication unit, which receives the control command. The communication units are configured to specify amongst themselves a master communication unit and to specify the remaining communication unit as slave communication units.

Abstract: Disclosed is a method of operating an elevator system having a plurality of elevator cars that are simultaneously and individually moveable in an elevator shaft between a plurality of floors. A predetermined travel route is assigned to an elevator car or a plurality of elevator cars. This travel route is defined by a sequence of stopping points that is fixed in advance for the respective elevator car and at which stopping points the respective elevator car is intended to make a planned stop. The elevator cars to which a travel route is assigned are then moved in accordance with the travel route assigned to the respective elevator car. Further disclosed is an elevator controller and to an elevator system for carrying out such a method.

Abstract: A method can be used to position a car door and a landing-stop door in a synchronized manner at a landing stop in an elevator shaft of an elevator system. The car door may be configured as a guide door, and the landing-stop door may be configured as a follower door. The method may involve bringing an elevator car close to the landing stop, upon entry of the car door into an unlock zone sensing a presence signal of the follower door by way of a presence sensor of the guide door, actuating the guide-door drive by way of the guide controller and executing an opening movement of the guide door, providing movement information of the guide door, and actuating the follower-door drive of the follower door.

Abstract: An elevator system includes at least one guide rail and at least one elevator cabin movable in a direction of travel along the guide rail. A cabin control unit is installed on the elevator cabin and a central control unit is connected to the cabin control unit by a wireless communications system. The wireless communications system includes a slotted waveguide conductor arrangement installed in the elevator shaft.

Abstract: The present disclosure concerns a method for operating an elevator system which comprises a shaft system and at least three cars, which is designed for separately moving the cars in at least a first direction of travel and in a second direction of travel. The at least three cars are moved separately in sequential operation each time and for each car a stop point at which the car can stop if necessary is continuously predicted at least for one direction of travel. The distance of the predicted stop points of neighboring cars from each other is thereby continuously determined. The elevator system is transferred to a safety mode if a negative distance of the stop points is determined.

Abstract: A drive arrangement includes a movable, rotatable rail segment of an elevator system. An electric motor moves the movable rail segment. The drive arrangement is configured to rotate the rail segment about an angle of rotation of less than 360°. An inverter unit provides electrical power to the electric motor and is configured to receive a control command relating to the position of the movable rail segment and provide the electrical drive power based on the control command. The drive arrangement forms two or exactly three drive segments. Each drive segment includes an inverter unit and a coil arrangement, which is supplied with electrical power by the assigned inverter unit. Each inverter unit includes a communication unit, which receives the control command. The communication units are configured to specify amongst themselves a master communication unit and to specify the remaining communication unit as slave communication units.

Abstract: An elevator car may comprise a sliding carriage for moving an elevator car along guide rails of an elevator installation designed as part of a linear motor, a receiving means disposed on the sliding carriage, and a load space with a load space floor that is supported by the receiving means. The load space may be vibration-related decoupled by way of one or more damping elements from the sliding carriage. The elevator car may also comprise a controllable actuating element disposed on the elevator car such that when activated the controllable actuating element enables a relative movement of the load space floor to the sliding carriage.

Abstract: The disclosure relates to an elevator system consisting of a plurality of elevator carriages, a shaft system, a drive system for separately moving the elevator carriages within the shaft system, as well as a safety system having a plurality of safety nodes designed to bring the elevator system into a safe operating mode if an operating mode of the elevator system, which deviates from the normal operation mode, is detected. The elevator carriages, the shaft system and the drive system form a functional unit. One of the safety nodes is always assigned to one of the functional units, wherein the safety nodes are each connected to at least another safety node through an interface for transmitting data. Each safety node includes at least one sensor, which detects an operating parameter of the corresponding assigned functional unit.

Abstract: An elevator system having a car which can be moved along an elevator shaft in a direction of travel. The elevator shaft includes a busbar that extends in the direction of the direction of travel. The car comprises a current collector that can be moved between a first position and a second position along a compression direction. In the first position, the current collector is in engagement with the busbar such that there is an electrical connection between the busbar and the current collector. In the second position, the current collector is disengaged from the busbar, such that the electrical connection between the busbar and the current collector is separated.

Abstract: The present disclosure concerns a method for operating an elevator system which comprises a shaft system and at least three cars, which is designed for separately moving the cars in at least a first direction of travel and in a second direction of travel. The at least three cars are moved separately in sequential operation each time and for each car a stop point at which the car can stop if necessary is continuously predicted at least for one direction of travel. The distance of the predicted stop points of neighboring cars from each other is thereby continuously determined. The elevator system is transferred to a safety mode if a negative distance of the stop points is determined.

Abstract: The disclosure relates to an elevator system consisting of a plurality of elevator carriages, a shaft system, a drive system for separately moving the elevator carriages within the shaft system, as well as a safety system having a plurality of safety nodes designed to bring the elevator system into a safe operating mode if an operating mode of the elevator system, which deviates from the normal operation mode, is detected. The elevator carriages, the shaft system and the drive system form a functional unit. One of the safety nodes is always assigned to one of the functional units, wherein the safety nodes are each connected to at least another safety node through an interface for transmitting data. Each safety node includes at least one sensor, which detects an operating parameter of the corresponding assigned functional unit.

Abstract: A device for checking guides of an elevator car that can be moved along guide rails may include means for measuring contact forces of the guides on the guide rails. The device may further include an evaluation unit. The means for measuring contact forces may be configured to make measured values determined by the means for measuring contact forces available to the evaluation unit, either through wired connection or wireless connection. In some cases, the means for measuring contact forces may measure contact forces on the guide rails in at least two different directions. Also disclosed are methods for balancing elevator cars.

Abstract: Described is a method performed by a computing device, the method comprises: deriving a hierarchal structure of hardware instances of a hardware block, wherein the hardware block is described in a register transfer language (RTL); determining complexity of at least one hardware instance, in the hierarchal structure, with reference to a complexity metric; identifying, in response to the determined complexity of the at least one hardware instance, whether the at least one hardware instance is to be modeled; and modifying the hierarchal structure with information about the to be modeled hardware instance.

Abstract: Described is a method performed by a computing device, the method comprises: deriving a hierarchal structure of hardware instances of a hardware block, wherein the hardware block is described in a register transfer language (RTL); determining complexity of at least one hardware instance, in the hierarchal structure, with reference to a complexity metric; identifying, in response to the determined complexity of the at least one hardware instance, whether the at least one hardware instance is to be modeled; and modifying the hierarchal structure with information about the to be modeled hardware instance.