An elevator car (1) defines an interior space (2) for accommodating passengers and/or cargo. The elevator car (1) includes a support frame (8) positioned above the interior space (2), a working platform (12) moveable between a stowed position, above the interior space (2), and an operational position, suspended within the interior space (2), and at least one suspension arrangement (14) arranged to suspend the working platform (12) from the support frame (8). The working platform (12) includes a platform opening (15) and a platform emergency escape door (13). The platform emergency escape door (13) is movable between a closed position in which the platform door (13) covers the platform opening (15) and an open position in which the platform emergency escape door (13) at least partially does not cover the platform opening (15).

This invention is directed to a self-propelled elevator system having multiple motors or one motor, and methods for synchronizing said multiple motors. This invention is also directed to an elevator brake system to be used in said self-propelled elevator system or other types of elevators to increase their level of safety.

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.

An elevator car of an elevator system includes a car body and a car frame supportive of the car body. The car frame includes two opposing side frames, each side frame formed from a plurality of side frame segments, including two upright members and one or more upright braces connecting the two upright members, adjacent side frame segments secured to each other via a joint. A method of installation of an elevator car of an elevator system includes positioning a first side frame segment of a plurality of side frame segments adjacent to second side frame segment of the plurality of side frame segments, and securing the first side frame segment to the second side frame segment via a splice joint thereby constructing a car frame of the elevator car. One or more car bodies are installed into the car frame.

An elevator car of an elevator system includes a car body, and a car frame supportive of the car body. The car frame includes two or more opposing upright assemblies, a crosshead assembly located above the car body, and a plank assembly located below the car body. A plurality of seismic retainers are located at each of the upright assemblies. The plurality of seismic retainers are configured for a non-contact relationship with a guide rail of the elevator system during normal operation of the elevator system, and configured to react guide rail loads during a sway event via contact with the guide rail.

Elevators and elevator car wall panel systems are provided herein. The systems include an elevator car frame, at least two wall panels pivotally connected to the frame, a connecting element operably connecting the at least two wall panels, and an actuation element operably connected to the connecting element, wherein the actuation element is operable to transition the at least two wall panels from a closed state to an open state.

Elevator car frames are provided. The elevator car frames include a first upright, a second upright, a first support element connected to the first upright, a second support element connected to the second upright, and a retractable crosshead having a first portion and a second portion extending between the first and second support elements, wherein the retractable crosshead is operable between a first state wherein the first portion and the second portion are connected and a second state wherein the first portion and the second portion are separated.

An elevator car includes a car box. The car box includes a frame structure that includes a floor element, vertical beams connected to the floor element, and roof beams connected to the vertical beams. The car box further includes walls, each including wall elements of rectangular shape fixed side-by-side to the frame structure and extending from one edge side of the car box to another. The car box includes a roof including roof elements of rectangular shape fixed side-by-side to the frame structure and extending from one edge side of the car box to another. The car box includes and interior bounded by at least the floor element, the walls, and the roof. At least on set of elements, of the roof elements and the wall elements, includes elements associated with separate, respective integrated functionalities.

An elevator installation system and method is disclosed that includes a support structure having a first surface and a second surface. The support structure is oriented such that the first surface faces in a first direction and the second surface faces in a second direction opposite the first direction. The system further includes a hoist supporting the support structure such that at least a portion of the hoist is positioned facing the second surface.

This invention is concerning a car suspending pulley device including a pair of beams provided parallel to each other on a lower portion of a car and a car suspending pulley arranged between the pair of beams and supported by the pair of beams. A weight suspending pulley is provided on a counterweight. The car and the counterweight are suspended from a main rope wrapped around the car suspending pulley and the weight suspending pulley. A compensating member is suspended between the beams and the counterweight. The compensating member includes a funicular body having a first end portion connected to only one of the pair of beams and a second end portion connected to the counterweight. The first end portion of the funicular body is located in a region of the one beam when viewed in a vertical direction.