According to embodiments, an overhead lift includes a lift actuator; and a control system communicatively coupled to the lift actuator. The control system may include a control unit comprising a processor with a memory communicatively coupled to the processor and having computer readable and executable instructions and at least one transceiver communicatively coupling the control unit to at least one of a computer, a network, and a data storage device. The processor executes the computer readable and executable instructions to: determine at least one operating characteristic of the overhead lift and an operating time of the overhead lift as the overhead lift is actuated; determine an accumulated load-time parameter for the overhead lift based on the at least one operating characteristic and the operating time; and upload the accumulated load-time parameter to at least one of the computer, the network, and the data storage device.

The present disclosure involves a belt drive mechanism which can be used to pay out or draw belt to or from a belt actuated system (or belt driven system). The mechanism features a self-winding spool which can automatically wind or unwind portions of the belt as they are withdrawn from, or fed to the belt actuated system. A second rotational axle (idler shaft), with one or more sheaves (e.g., pulley's or rollers) can be rotationally coupled to a capstan via a belt, and can be utilized to drive additional mechanisms in the belt drive mechanism, such as a winding mechanism.

A portable hoist system has an adjustable support strut mechanism, allowing for compact storage and portability, with the entire assembly retained as one unit. In one embodiment the support strut mechanism, which is connected on one end to a boom and at another end to a bracket, is foldable and adjustable using an adjustment pin and holes along the two-piece support strut mechanism. In one preferred form of the invention a winch of the hoist system is field-adjustable as to position on the hoist's boom, to overcome problems of space constraints.

A portable hoist system has an adjustable support strut mechanism, allowing for compact storage and portability, with the entire assembly retained as one unit. In one embodiment the support strut mechanism, which is connected on one end to a boom and at another end to a bracket, is foldable and adjustable using an adjustment pin and holes along the two-piece support strut mechanism. In one preferred form of the invention a winch of the hoist system is field-adjustable as to position on the hoist's boom, to overcome problems of space constraints.

A heavy load lifting system is a system that enables a repairman to safely lift and mount different vehicle components for maintenance or repair. The system may include an elongated frame, a wheeled base, a height-adjustment carriage, a telescopic boom, a pivot support assembly, a tilt-adjustment mechanism, and a winch mechanism. The elongated frame enables the height-adjustment carriage to be raised so that the vehicle component can be removed from the vehicle. The wheeled base enables the system to be moved around. The height-adjustment carriage enables the operator to elevate or lower the telescopic boom. The telescopic boom enables the vehicle component to be removed safely. The pivot support assembly provides additional support to the vehicle component being removed. The tilt-adjustment mechanism enables the telescopic boom to position the removed vehicle component at the desired orientation. The winch mechanism enables the height-adjustment carriage to be moved along the elongated frame.

A device designed for the removal, storage, and installation of removable hardtops from convertible sport utility vehicles, comprising a wheeled base unit, a vertical support structure and a platform assembly, wherein the base unit is aligned directly below the platform unit and the vertical support structure connects them together, wherein the device can be disassembled for simple shipping, is adjustable for height and depth to accommodate different SUV models, and includes markers for easy assembly.

The focus of the present disclosure is on portable cranes and cantilevered base systems. In particular, portable cranes and cantilevered base systems which are lightweight, easy-to-operate, safe, inexpensive, and have extended reaches with high-load capacities would be advantageous for a variety of applications. A cantilevered support to a pivotable arm that is provided by the present disclosure provides advantages when compared to other portable cranes, such as the ability to: 1) extend an arm and reach of a crane, 2) increase a load that can be lifted or lowered, 3) operate a portable crane and cantilevered base system freestanding without attaching a base to a floor, surface, or bed of a vehicle, and 4) augment the structural capacity of a portable crane and cantilevered base with mechanical devices to support a variety of applications.

A weight balancing gantry has a tower having a fixed length radial arm pivotally coupled from a pivot point at an upper end of the tower. An angle strut acts between the tower and the radial arm across the pivot point. A pivot point pulley is located at the upper end of the tower and a weight balancing mechanism located at the tower. A bogey runs along the radial arm and has a bogey pulley. A positioning mechanism at the radial arm has at least one controlled cylinder for positioning and holding the bogey along to the radial arm. A cable runs from the weight balancing mechanism, up across the pivot point pulley and over the bogey pulley to attach to an industrial tool.

A weight balancing gantry has a tower having a fixed length radial arm pivotally coupled from a pivot point at an upper end of the tower. An angle strut acts between the tower and the radial arm across the pivot point. A pivot point pulley is located at the upper end of the tower and a weight balancing mechanism located at the tower. A bogey runs along the radial arm and has a bogey pulley. A positioning mechanism at the radial arm has at least one controlled cylinder for positioning and holding the bogey along to the radial arm. A cable runs from the weight balancing mechanism, up across the pivot point pulley and over the bogey pulley to attach to an industrial tool.

A movable lifting bracket relates to a field of lifting bracket and includes bearing frames, a main frame, and a mobile frame arranged on a lower portion of the main frame. Universal wheels and directional wheels are arranged on a lower portion of the movable frame. Adjusting sleeves are arranged on upper ends of the movable frame. First through holes are on an outer side of each of the adjusting sleeves. Lower ends of the main frame are inserted into the adjusting sleeves. A first limit pin is arranged on the outer side of each of the adjusting sleeves; A pressing frame is arranged on the main frame.