According to an aspect, there is provided a method for managing elevator cars in a multi-car elevator shaft system. The method comprises determining, by an elevator control entity, the optimum number of elevator cars for a given time of a day in the multi-car elevator shaft system; and commanding, by the elevator control entity, at least one elevator car into at least one elevator car storage or back to service from the at least one elevator car storage based on the determination, wherein elevator cars in the at least one elevator car storage act as standby elevator cars for the multi-car elevator shaft system.

Vehicle parking information is used to control an elevator system. The vehicle parking information indicates that at least one parking space is occupied, and one or more elements of the elevator system may be controlled based on the vehicle parking information. An apparatus, a method and a computer program are provided.

Disclosed is a car mover, configured to move an elevator car in lane of a hoistway, having: a power supply configured to power one or more motors to drive a respective one or more wheels; a car mover controller operationally connected to the power supply and a supervisory controller operationally connected to the car mover controller, wherein the car mover controller and the supervisory controller are configured to execute health monitor protocols to thereby: monitor a state of charge (SOC) of the power supply; and control the car mover in response to determining that the power supply is in a low SOC.

A method for positioning a plurality of elevator cars that includes determining an occupant count for each of a plurality of locations, by determining the number of occupants exiting the plurality of elevator cars at each of the plurality of locations and the number of occupants entering the plurality of elevator cars from each of the plurality of locations. The method includes moving at least one of the plurality of elevator cars to a first location with a total occupant count that is greater than the occupant count at each respective location of the plurality of locations when the at least one of the plurality of elevator cars is in an inactive state.

An intelligent normal force release supervisor including: a processor; and a memory including computer-executable instructions that, when executed by the processor, cause the processor to perform operations, the operations including: receiving a signal from a dispatching controller that an elevator car and a propulsion system are going to park for a selected period of time; requesting a confirmation from a brake controller to confirm that a brake system of the elevator car and the propulsion system are deployed; receiving the confirmation from the brake controller to confirm that the brake system of the elevator car and the propulsion system are deployed; and transmitting a command to a normal force controller to reduce normal force on wheels of the propulsion system, wherein the normal force controller is configured to actuate a normal force generator to reduce the normal force on the wheels of the propulsion system in response to the command.

According to an aspect, there is provided a method for determining the number of elevator cars in a two-shaft multi-car elevator system. The method comprises determining the number of active elevator cars N in the two-shaft multi-car elevator system by $N=\frac{\mathrm{RTT}*\mathrm{arr}}{a*\mathrm{carsize}},$
wherein RTT is a round trip time of the two-shaft multi-car elevator system, arr is the arrival rate of passengers, a is a car load factor, and carsize is the number of passengers one elevator car is able to carry.

A multicar elevator system includes a group of individually drivable elevator cars and two shafts coupled to each other with at least two transfer channels. The system further includes a control unit configured to operate the system in either of two operating modes, wherein in the first mode the group of elevator cars is arranged to travel to a first vertical direction in the first shaft and to another vertical direction in the second shaft through the transfer channels. In the second mode, a first sub-group of elevator cars are parked in one of the shafts and at least one elevator car belonging to a second sub-group of elevator cars is arranged to travel in the both vertical directions in the other shaft upon a call.

A method of adjusting a load setting of an elevator car that includes receiving one or more load measurements associated with the elevator car and determining a maximum load of the elevator car from the one or more load measurements. The method further includes generating a modified load setting for the elevator car based on the maximum load and replacing the load setting of the elevator car with the modified load setting.

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: an elevator control; a plurality of individually movable elevator cars driving in an elevator runway system including at least one elevator runway, preferably at least two elevator runways, whereby the number of elevator cars is higher than the number of elevator runways in the runway system. The elevator cars are movable in the elevator runway system via at least one drive system. Each of the elevator cars is provided with an identifier. The elevator system includes at least one reader device for the identifier and a car handling module in the elevator control processing the information on the elevator cars and their identifiers in connection with their position in the elevator system. The elevator system includes elevator cars differing in at least one parameter (differing parameter). The memory of the elevator control includes car parameters of the cars in operation in the elevator system and the elevator control is configured to use the car parameters in the control of the elevator system. The identifier includes information at least about the differing parameter, and the car handling module is configured to put out of use the car parameters of an elevator car that is to be put out of operation and/or to introduce the car parameters of an elevator car which is to be put into operation.