A lifting member for an elevator system includes a rope formed from plurality of load carrying fibers extending along a length of the lifting member. The plurality of load carrying fibers including a plurality of aromatic polyester based fibers. A coating layer at least partially encapsulates the rope. An elevator system includes a hoistway, an elevator car disposed in the hoistway and movable therein, and a lifting member operably connected to the elevator car to suspend and/or drive the elevator car along the hoistway. The lifting member includes a rope formed from plurality of load carrying fibers extending along a length of the lifting member. The plurality of load carrying fibers including a plurality of aromatic polyester based fibers. A coating layer at least partially encapsulates the rope.

The invention relates to an elevator arrangement, comprising a hoistway one or more vertically oriented guide rail lines in the hoistway for guiding vertical movement of one or more movable elevator units, and one or more movable elevator units mounted in the hoistway vertically movably along one or more guide rail lines, including at least an elevator car, preferably also a counterweight, and a hoisting roping; a movable support structure mounted in the hoistway for supporting said one or more movable elevator units below it via said hoisting roping, and a hoisting machine on the movable support structure for moving the hoisting roping, for thereby moving said one or more movable elevator units. Said movable support structure comprises a body portion, and a shelf structure projecting laterally from the body portion, and the hoisting machine is mounted on the shelf structure. The invention also relates to a method for constructing an elevator implementing the arrangement.

The present application relates to the technical field of lifting equipment, and provides a traction machine and a lifting equipment. The traction machine includes traction pulleys, traction ropes driven by the traction pulleys and fixed pulleys for changing directions of the traction ropes. The fixed pulley is provided with a sensor sensing member rotating with the fixed pulley, a traction machine sensor is arranged beside the fixed pulley; the traction machine sensor is configured to detect a rotation speed of the sensor sensing member, and send the rotation speed to a controller of the traction machine; the controller controls a rotation of the traction pulley according to detected data of the traction machine sensor. Since this kind of traction machine is provided with the sensor sensing member and the traction machine sensor, it is capable of detecting whether the traction machine has an abnormal operation, and stopping the traction machine immediately in an abnormal state.

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.

An elevator system includes a hoistway, a rail extending along the hoistway and an elevator car located in and movable along the hoistway. A drive assembly is operably connected to the elevator car and includes two or more wheels engaged to opposing surfaces of the rail. The drive assembly is configured to apply an engagement force to the rail to both support the elevator car at the rail and drive the elevator car along the rail.

A jump elevator includes a machine room provided in the hoistway and configured to be fixed or movable relative to the hoistway; at least one lifting assembly comprising: a frame attached to the outside of the hoistway and partially extending into the hoistway; a pulley assembly including a winch, a fixed end, and a plurality of pulleys disposed on the machine room and the frame; wherein a pulling line is disposed between the winch, the plurality of pulleys, and the fixed end; wherein the at least one lifting assembly is disposed below the covering portion of the hoistway.

Disclosed is a method of expanding an elevator system in a hoistway, involving: connecting an elevator car at a first level to an overhead winch that is connected to a hoist-beam at a second level, the elevator car being supported by a rail system, the rail system defining, at a first level, first and second rails with first and second rail terminal ends; connecting a machine system mounted to the first rail terminal end to a machine hoist mounted at the second level; removing a dead-end hitch from the second rail terminal end; hoisting the machine system to the second level; extending the rail system to the second level to define third and fourth rail terminal ends; hoisting the elevator car and the dead-end hitch to the second level; and installing the machine system and the dead-end hitch at the second level, to the third and fourth rail terminal ends.

An illustrative example embodiment of an elevator includes an elevator car frame. A drive mechanism is situated near only one side of the elevator car frame. The drive mechanism includes at least one rotatable drive member that is configured to engage a vertical surface near the one side of the elevator car frame, selectively cause movement of the elevator car frame as the rotatable drive member rotates along the vertical surface, and selectively prevent movement of the elevator car frame when the drive member does not rotate relative to the vertical surface. A biasing mechanism urges the rotatable drive member in a direction to engage the vertical surface. At least one stabilizer is situated near the one side of the elevator car frame and is configured to prevent the elevator car frame from tipping away from the vertical surface.

Disclosed is a method of expanding an elevator system in a hoistway, involving: connecting an elevator car at a first level to an overhead winch that is connected to a hoist-beam at a second level, the elevator car being supported by a rail system, the rail system defining, at a first level, first and second rails with first and second rail terminal ends; connecting a machine system mounted to the first rail terminal end to a machine hoist mounted at the second level; removing a dead-end hitch from the second rail terminal end; hoisting the machine system to the second level; extending the rail system to the second level to define third and fourth rail terminal ends; hoisting the elevator car and the dead-end hitch to the second level; and installing the machine system and the dead-end hitch at the second level, to the third and fourth rail terminal ends.

A foldable elevator cabin and a foldable elevator shaft are disclosed. The foldable elevator cabin has a plurality of members attached at a centralized point for centralized folding using arms attached between each member. A ceiling and a base are attached to the top and bottom of the various members. Secondly, a foldable elevator structure having a plurality of members is shown having each member sequentially attached between a preceding member and a succeeding member until all members have been attached. In this fashion, the foldable structure is foldable between each set of two adjacent members.