A stationary type caring lift includes a base plate arranged on a floor part at each of head and foot sides of a bed for a care receiver along each short-side side of the bed, four supports erected on the base plates in the vicinity of four corners of the bed, a pair of guide rails supported above the bed by the four supports and arranged in parallel along both long-side sides of the bed, a longitudinally moving body arranged between the guide rails and capable of being moved in a longitudinal direction of the bed while being guided by the guide rails, a slide rail attached movably, a laterally moving body attached movably in the lateral direction of the bed, and a lifting drive mechanism attached in the laterally moving body for hanging down the care receiver and having a worm reduction gear with a self-lock function.

Sling bars, lift systems, and methods of attaching a subject sling to a sling bar are disclosed. A sling bar includes a bar extending in a longitudinal direction, a protrusion extending from an upper part of the bar, a sling attachment portion extending to define a receiving aperture, a terminus of the sling attachment portion facing the protrusion, defining an opening into the receiving aperture, the protrusion defining an undercut portion of the receiving aperture, a retention latch pivotally coupled to the protrusion and defining an engagement face that selectively interfaces with a stop surface at the terminus in a closed position to cover the opening, the retention latch being constrained to pivot to an open position whereby the retention latch ceases to interface with the stop surface at the terminus, and a biasing mechanism coupled to the retention latch to force the retention latch toward the closed position.

Support harnesses and systems and kits including the same are disclosed. A support harness includes a plurality of straps arranged such that a first strap, a second strap, and a third strap are spaced apart from one another, and the third strap extends between the first strap and the second strap. The support harness further includes a first connection piece extending between a proximal end of the first strap and a proximal end of the third strap and a second connection piece extending between a proximal end of the second strap and the proximal end of the third strap. The first strap, the second strap, and the third strap are each positionable around a horizontally positioned subject by wrapping the respective distal ends around a body part of the horizontally positioned subject and coupling the distal ends to the respective portions.

A multi-link device includes a load tension pin including a sensor configured to measure tension applied to the load tension pin, network interface hardware, one or more processors, and one or more memory modules storing computer readable and executable instructions which, when executed by the one or more processors, cause the multi-link device to: determine whether the tension measured by the load tension pin exceeds a threshold value; and transmit, by the network interface hardware, load event data to a receiver in response to determination that the tension exceeds the threshold value.

An example assistive ambulation system is described herein. The system includes a walker including a base frame, a walker frame attached to the base frame, a plurality of rolling members attached to the base frame, and a hoist attached to the walker. The base frame includes a pair of support members and a base cross member. Each of the support members extends between forward and rearward ends of the walker. Additionally, the pair of support members are spaced apart and substantially parallel to one another. The base cross member extends transversely between the pair of support members. The walker frame includes a pair of bent posts and a walker cross member. Each of the bent posts extends upward from the base frame. Additionally, the pair of bent posts are spaced apart and substantially parallel to one another. The walker cross member extends transversely between the pair of bent posts.

The invention provides an electronically control motorized lifting device for transfer of a paraplegic between seated positions. A post extends from a wheeled base and movably supports a head for upwards and downwards movement. A lifting arm arrangement is pivotably secured to the head. The head is also rotatable about the post and the base movable between an expanded stabilizing condition and a retracted condition. The latter condition allows the lifting device to fit through a standard width doorway. Movement of the base between these conditions is effected by pivoting of the lifting arm arrangement into and out of a lateral supporting position. The base preferably includes five legs extending substantially radially from the post with two of the legs foldable towards adjacent legs.

A support structure and method for at least partially elevating a person via a hoist are provided. The support structure is connectable to or forms part of a retention structure secured around a person. At least two connectors are configured for connecting to the hoist, the at least two connectors being located or locatable to enable selection of a first set of positions or a second set of positions at which the hoist is connectable to the support structure. Each of the first set of positions and the second set of positions extend along a span of a longitudinal axis of the retention structure. The span of the second set of positions differs from the span of the first set of positions.

According to embodiments, a method for operating a lifting device monitoring with a control unit, monitoring current supplied to the lift actuator when the lift actuator is actuated; discontinuing the current supplied to the lift actuator when the current exceeds a current threshold value; determining an accumulated number of overload stops based on the current supplied to the lift actuator; determining at least one operating characteristic of the lifting device and an operating time of the lifting device as the lifting device is actuated; determining an accumulated load-time parameter for the lifting device based on the at least one operating characteristic and the operating time; and uploading, with a transceiver, at least one of the accumulated number of overload stops and the accumulated load-time parameter to at least one of the computer, the network, and the data storage device.

A multi-link device includes a load tension pin including a sensor configured to measure tension applied to the load tension pin, network interface hardware, one or more processors, and one or more memory modules storing computer readable and executable instructions which, when executed by the one or more processors, cause the multi-link device to: determine whether the tension measured by the load tension pin exceeds a threshold value; and transmit, by the network interface hardware, load event data to a receiver in response to determination that the tension exceeds the threshold value.

According to embodiments, a method for operating a lifting device monitoring with a control unit, monitoring current supplied to the lift actuator when the lift actuator is actuated; discontinuing the current supplied to the lift actuator when the current exceeds a current threshold value; determining an accumulated number of overload stops based on the current supplied to the lift actuator; determining at least one operating characteristic of the lifting device and an operating time of the lifting device as the lifting device is actuated; determining an accumulated load-time parameter for the lifting device based on the at least one operating characteristic and the operating time; and uploading, with a transceiver, at least one of the accumulated number of overload stops and the accumulated load-time parameter to at least one of the computer, the network, and the data storage device.