An elevator system is provided including a hoistway having a plurality of landings. An elevator car is configured to move within the hoistway between the plurality of landings. A plurality of guide rails guide movement of the elevator car and a counterweight within the hoistway. Each guide rail includes a base and a blade. A machine assembly is mounted within the hoistway and includes a traction sheave rotatable about an axis. The traction sheave is configured to drive movement of the elevator car between the plurality of landings. At least one of the plurality of guide rails is arranged in an overlapping configuration with the machine assembly such that a plane defined by the base of the guide rail is parallel to the axis and intersects a portion of the traction sheave.

A construction site elevator system temporarily bridges at least part of the distance between the top stop of a jump lift and the top work level on the construction site. The construction site elevator system includes a frame structure and an elevator within the frame structure, the frame structure being configured to be insertable into an elevator shaft and being mountable at different positions in the elevator shaft.

An elevator system for installation on the outside of a building which extends over at least two stories and includes a shaft, a car movably mounted in the shaft for movement in a longitudinal direction of the shaft, and a drive for the car. The shaft has a shaft pit at its lower end and a through-opening for each story to be served and is configured as a prefabricated sheet-metal box made of at least one thin-walled steel plate that also extends beyond the shaft pit. The sheet-metal box forming the shaft is self-supporting, in that the steel plates extend in a straight line in the longitudinal direction of the shaft, and are profiled in a plane extending at right angles to the longitudinal direction. The steel plates are formed in one piece over the entire extent of the shaft in the longitudinal direction. A method for producing this elevator system is also provided.

A method is disclosed of retrofitting an elevator machine with primary and secondary braking, the machine being disposed on a machine support frame in an elevator machine room, and engaging one or more ropes for providing selective movement of an elevator car disposed in an elevator shaft, the machine having a drive sheave including a cylindrical brake drum, and brake components including dual brake arms; the method including: removing the brake components; affixing flanged disc segments about the drum and interlocking the flanged disc segments to form a brake rotor; and mounting respective brake calipers to frame mounts for providing primary and secondary braking to the elevator machine.

A method for refinishing a surface structure of shaft material of an elevator, which extends along a shaft, enables the use of image data to determine an absolute position and/or speed of an elevator car. The elevator includes the elevator car, which is movable in the shaft, a camera, which is arranged at the elevator car and generates the image data from the surface structure, and an evaluating unit, which determines the absolute position and/or the speed of the elevator car from the image data. The surface structure is refinished at least locally in order to increase a distinctiveness of the surface structure in the image data. The shaft material can be, for example, a guide rail, a fastening element of the guide rail, or a shaft wall.

An elevator system includes a hoistway and an elevator car suspended in the hoistway via one or more suspension members. A counterweight is suspended in the hoistway via the one or more suspension members to balance operation of the elevator car. A machine is positioned at the hoistway to drive the one or more suspension members along the hoistway, driving motion of the elevator car and/or counterweight along the hoistway. A suspension member termination is supported at the machine, to secure an end of the one or more suspension members. A drive system for an elevator includes one or more elevator suspension members and a machine interactive with the one or more elevator suspension members to drive motion of an elevator car. A suspension member termination is supported at the machine to secure an end of the one or more suspension members at the machine.

A wireless power transfer system for wirelessly powering a conveyance apparatus of a first conveyance system and a conveyance apparatus of a second conveyance system including: a wireless electrical power transceiver located along a surface of the conveyance apparatus of the first conveyance system, a wireless electrical power transceiver located along a surface of the conveyance apparatus of the second conveyance system, the surface of the conveyance apparatus of the second conveyance system being opposite of the surface of the conveyance apparatus of the first conveyance system, wherein the wireless electrical power transceiver of the first conveyance system is configured to wirelessly transfer electrical power to the wireless electrical power transceiver of the second conveyance system when the wireless electrical power transceiver of the first conveyance system and the wireless electrical power transceiver of the second conveyance system are located proximate to one another.

An elevator system includes an elevator car that is movable in an elevator shaft in the vertical direction, a closed support belt guided about a lower deflection roller and an upper deflection roller and a drive machine driving the support belt. A drive connection is made between the support belt and the elevator car with a coupling device arranged on the elevator car that is coupled to a coupling element of the support belt. The coupling element is a connection element that connects two free ends of the support belt together.

Climber motors are a form of temporary winch that can be used before a permanent elevator drive system is installed at the top of a hoistway. A mount to be employed with such a climber motor may include a frame having a base, a lower portion, and an upper portion. The upper portion may support a lower plate, which lower plate supports sleeves, which sleeves in turn support an upper plate. The frame and the climber motor may be positioned within an elevator cab such that the sleeves extend upwards through apertures in a canopy of the elevator cab. Once the upper plate is positioned between the sleeves and a crosshead above the elevator cab, the climber motor may be engaged to cause the sleeves to exert an upward force on the crosshead and thereby lift the elevator cab in the hoistway.

A linear motor arrangement for an elevator installation and a car movable along a first and second track. The linear motor arrangement is configured to drive the car. The linear motor arrangement includes a first drive train arranged along the first track, and a second drive train arranged along the second track. The first drive train differs from the second drive train in at least one property and forms an angle relative to the second track. A linear motor arrangement is disclosed for an elevator installation, wherein the elevator installation includes a car which is movable along a first and second track. The linear motor arrangement comprises a first drive train arranged along the first track, and a second drive train arranged along the second track, wherein the first drive train is configured to provide a higher drive power density than the second drive train.