An exemplary elevator system includes an elevator car (22) having an integrated cabin and car frame structure including a platform thickness (T) between a floor surface in the cabin and a lowermost surface on a support beam used for supporting the car beneath the floor surface. A sheave assembly (26) is supported beneath the floor surface. The sheave assembly includes a plurality of sheaves and a plurality of subframe beams. The sheaves and subframe beams fit within the platform thickness (T) such that the subframe beams and the sheaves are no lower than the lowermost surface on the support beam. A plurality of isolation members are between the sheave assembly and the elevator car for isolating an interior of the cabin from vibrations associated with movement of the sheaves (26).

An elevator car arrangement includes an elevator car body and an elevator car sling. The elevator car arrangement further includes a hanging damper arranged to connect the elevator car body and the elevator car sling together for dampening vibrations coming from guide rails through the elevator car sling to the elevator car body. The hanging damper includes a first part connected to a bottom part of the elevator car body; a second part connected to the elevator car sling; and a damping element arranged to dampen vibrations coming from the second part to the first part. A method for dampening vibrations coming from guide rails through the elevator car sling to the elevator car body is disclosed.

A method for balancing an elevator car including a frame; a cabin box mounted on the frame; and a plurality of elastic members, such as springs, in vertical direction between the frame and the cabin box, via which elastic members the cabin box rests on the frame. The method includes measuring the vertical distance between the frame and the cabin box in several horizontally spaced apart locations with distance sensors; and adjusting the weight distribution of the cabin box by adding and/or removing weight elements on the cabin box. An arrangement for balancing an elevator car is provided to implement the method.

An elevator car is constructed and arranged to move along a hoistway. The car includes a cab support from below by a platform. A vertical member is connected to the platform via a flex joint and extends upward from platform for further elevator cab support. The flex joint facilitates cab isolation from vibration and noise.

A ropeless elevator system includes a vertically extending first lane, a vertically extending second lane, and a transfer station extending between and in communication with the first and second lanes. An elevator car is disposed in and is constructed and arranged to move through the transfer station and the first and second lanes. A propulsion system of the elevator system propels the elevator car through at least the first and second lanes and carries a supplemental DC energy storage device for providing supplemental energy to the elevator car during normal operation. A wireless power transfer system of the elevator system is configured to periodically charge the DC energy storage device.

An elevator in which hoisting ropes pass under first and second diverting pulleys, in which a suspension device crosses a line between guide rails. The first and second diverting pulleys may be mounted on the suspension device such that the first and second diverting pulleys may be on a first side and a second side, respectively, in which the sides being opposite, of the line between the guide rails. A frame of the elevator car may be mounted on the suspension device which is supported by a first suspension point and a second suspension point. The first suspension point and the second suspension point may be at a horizontal distance from each other and on opposite sides of each other, and that the first and second suspension points may be on a line between the guide rails or on a line parallel with the guide rails.

An elevator passenger car allows enhancement of rigidity of a lower beam with a simple configuration while suppressing an increase in the number of components, and includes an upper beam disposed at an upper side, a pair of vertical frames having upper ends connected to both ends of the upper beam, a lower beam disposed between lower ends of the pair of vertical frames while having both ends connected, and a pair of underfloor side surface beams which are mounted and connected onto both ends of the lower beam while extending orthogonal thereto. The elevator passenger car has a car room disposed at a part defined by the upper beam, the pair of vertical frames, and the lower beam that is mounted on the pair of underfloor side surface beams. An underfloor side surface beam reinforcing member is provided for each of the pair of underfloor side surface beams.

The invention relates to an elevator car comprising a pulley frame; and a cabin frame mounted on the pulley frame; and one or more pulleys mounted on the pulley frame; and at least one elastically deformable support member between the cabin frame and the pulley frame via which at least one elastically deformable support member the cabin frame rests on the pulley frame. The elevator car comprises at least one parallel motion linkage mechanism connecting the cabin frame pivotally to the pulley frame, and arranged to allow the cabin frame to pivot up and down relative to the pulley frame, and to keep their relative angle unchanged. The invention also relates to an elevator implementing the car.

A car arrangement includes: a first car and a second car arranged one above the other in a car frame; wherein at least the first car is displaceable along the car frame in the direction of a vertical axis by a spindle drive; wherein the spindle drive includes a spindle and a drive unit; wherein the spindle drive is guided through a cutout in a support structure of the car frame, and the drive unit has a housing with a fastening flange fastening the housing to the support structure; and wherein the housing has first and second positions in relation to the cutout, the fastening flange exposing the cutout in the first position so the spindle drive can be guided through the cutout in the direction of the vertical axis, and the fastening flange projects beyond an outer edge of the cutout in the second position.