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.

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.

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.

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.

Method and apparatus for a wall mounted motorized storage system wherein a storage tray for holding items in storage is mourned on a framework having upper and lower, and either left or right side frame members which are mounted directly onto the wall of a building structure wherein left and right vertical rails provide a roller system for moving the storage tray up and down in response to movement of left and right chains which are driven by an electrically powered winch system. The lifting system also includes an upper rotating bar having left and right chain contacting sprockets thereon which the electrical winch engages and which moves the tray upwardly and downwardly. The electrically powered winch is controlled by a remote control.

An overspeed brake system for use in an elevator powerhead is provided. A brake rotor is attachable to a cable drum to rotate with a cable drum. A brake member selectively engages the brake rotor upon transition of an actuation lever from a first position to a second position. A biasing member acts on the actuation lever to bias the actuation lever from the first position towards the second position. A latch arrangement has a first orientation maintaining the actuation lever in the first position and a second orientation releasing the actuation lever for transitioning from the first position to the second position. The latch arrangement transitions from the first orientation to the second orientation when a speed sensing arrangement senses that the rotational speed of the cable drum is at least a predetermined rotational speed.

An overspeed brake system for use in an elevator powerhead is provided. A brake rotor is attachable to a cable drum to rotate with a cable drum. A brake member selectively engages the brake rotor upon transition of an actuation lever from a first position to a second position. A biasing member acts on the actuation lever to bias the actuation lever from the first position towards the second position. A latch arrangement has a first orientation maintaining the actuation lever in the first position and a second orientation releasing the actuation lever for transitioning from the first position to the second position. The latch arrangement transitions from the first orientation to the second orientation when a speed sensing arrangement senses that the rotational speed of the cable drum is at least a predetermined rotational speed.

A hoist security arrangement for avoiding dropping of the load when the chain or cable breaks includes a longer redundant auxiliary chain or cable disposed alongside the main chain or cable and which is raised and lowered synchronously with the slightly shorter main chain or cable so that the main chain or cable normally supports the entire weight of the load. If the main chain or cable breaks, the load drops slightly until the slack in the redundant auxiliary chain or cable is eliminated to hold the load solely by tensioning the auxiliary chain or cable. The extent of slack is set to insure that slight lengthening of the main chain as caused by wear does not result in loading of the auxiliary chain or cable.

A hoist security arrangement for avoiding dropping of the load when the chain or cable breaks includes a longer redundant auxiliary chain or cable disposed alongside the main chain or cable and which is raised and lowered synchronously with the slightly shorter main chain or cable so that the main chain or cable normally supports the entire weight of the load. If the main chain or cable breaks, the load drops slightly until the slack in the redundant auxiliary chain or cable is eliminated to hold the load solely by tensioning the auxiliary chain or cable. The extent of slack is set to insure that slight lengthening of the main chain as caused by wear does not result in loading of the auxiliary chain or cable.

A hoist security arrangement for avoiding dropping of the load when the chain or cable breaks includes a longer redundant auxiliary chain or cable disposed alongside the main chain or cable and which is raised and lowered synchronously with the slightly shorter main chain or cable so that the main chain or cable normally supports the entire weight of the load. If the main chain or cable breaks, the load drops slightly until the slack in the redundant auxiliary chain or cable is eliminated to hold the load solely by tensioning the auxiliary chain or cable. The extent of slack is set to insure that slight lengthening of the main chain as caused by wear does not result in loading of the auxiliary chain or cable.