A person lifting apparatus includes a strap movement system. The person lifting device includes a housing and a lifting strap feeding device located in the housing. The lifting strap feeding device includes a motor connected to a drum and a lifting strap wound on the drum. A sensor provides a signal indicative of force on the lifting strap. A controller receives the signal from the sensor. The controller controls operation of the motor based on the signal. A user input is used to place the strap movement system in a fast mode during which the controller speeds up operation of the motor from a normal operating speed.

The present disclosure may relate to a wheel that may include first and second exoskeleton plates. The wheel may also include first and second roller guide assemblies that each include one or more bearings, a roller guide coupled with the one or more bearings, and a shaft spanning the first and second exoskeleton plates and coupled with the roller guide such that the roller guide rotates around the shaft. The wheel may also include a tire and a centerless rim coupled with the tire. The centerless rim may be configured to have a shape that corresponds to a shape of the roller guide, and the roller guide may be configured to contact the centerless rim as the centerless rim rotates. The wheel may also include a first limiter to maintain contact between the centerless rim and the roller guide, and a second limiter.

A modular system is usable to vary the conditions around a bed in a home to provide various levels of support for patients who are at home and have varying acuity of medical complications. The modular system allows the home bed to be temporarily adapted for medical care.

A patient support apparatus includes a frame having a patient support deck. A footboard is removably coupled to the frame. A compression therapy module is located inside the footboard or is mounted to a foot section of the frame. A sleeve port is pneumatically coupled to the compression therapy module and is located on the foot section. The sleeve port is configured for attachment to at least one tube extending from a compression sleeve worn on a limb of a patient. Control circuitry is coupled to the frame and is operable to control functions of the patient support apparatus and to control the compression therapy module. A graphical display screen is coupled to the control circuitry and displays user inputs that are selected to control functions of the patient support apparatus and the compression therapy module.

A support device includes a base portion, a leg coupled to the base portion, the leg including an upper segment, a central segment pivotally coupled to the upper segment at a front wheel, a lower segment pivotally coupled to the central segment, a rear wheel coupled to the lower segment, and an engagement member coupled to the lower segment, where the engagement member is positionable between a disengaged position, in which at least a portion of the engagement member is positioned above the rear wheel, and an engaged position, in which at least a portion of the engagement member is positioned at or below the rear wheel.

A patient transport apparatus transports a patient over a floor surface. The patient transport apparatus comprises a support structure and support wheels coupled to the support structure. An auxiliary wheel is coupled to the support structure to influence motion of the patient transport apparatus over the floor surface to assist users. An actuator is operatively coupled to the auxiliary wheel and operable to move the auxiliary wheel relative to the support structure from a retracted position to a deployed position. A user interface sensor is operatively connected to the actuator and configured to generate signals responsive to the user touching the user interface. A controller is operatively coupled to the user interface sensor and the actuator to operate the actuator in response to detection of signals.

The present disclosure relates to a system and method for controlling the pressurization of a support structure for handling of a person, the support structure comprising: a body comprising a row of at least two elongated sections adapted to be pressurized; a carrier plate, wherein, in a pressurized loaded condition of one or more of the elongated sections, the carrier plate is adapted to form an at least partially concavely curved front surface; a power unit adapted to pressurize one or more parts of the support structure individually via a respective valve; one or more sensors adapted to measure movements of the person and/or variations or deviations in pressurized parts of the support structure; and a controller configured to control the power unit to pressurize each part of the support structure that is adapted to be pressurized individually, based at least on sensor measurement data from the one or more sensors.

Devices, systems, and methods are described including a wearable lift device including a flexible material having a shape sufficient to encircle a portion of a subject's body; a fastener configured to secure the flexible material around the portion of the subject's body; at least one lift attachment element associated with the flexible material at one or more lift attachment sites, the at least one lift attachment element configured to attach the wearable lift device to a lift apparatus; a load sensor associated with at least one of the one or more lift attachment sites or along a load path between the one or more lift attachment sites; a microcontroller including circuitry configured to receive and process information regarding the measured load; and a reporting device operably coupled to the microcontroller and configured to transmit one or more signals indicative of the processed information regarding the measured load.

A system for supporting and positioning a person. A flexible cover layer defines a support surface for the person, and a formable layer is coupled to the flexible cover layer. The formable layer includes a sealed bladder adapted to be in fluid communication with a vacuum source, and particles disposed within the sealed bladder. The system is operable in a first configuration in the absence of the vacuum, and a second configuration in the presence of the vacuum. In the first configuration, the particles are substantially movable relative to one another such that a contour may be provided to the support surface. In the second configuration, substantially immovable relative to provide rigidity to the formable layer to maintain the contour. A controller coupled to sensors may control the vacuum source to move said system between the first and second configurations. Methods of supporting and positioning the person are also disclosed.

A system for supporting or positioning a patient before, during, or after a medical procedure can include a platform configured to support at least a portion of a patient. A support column can be positioned beneath the platform. A base can be positioned beneath the support column and configured to support the support column. The base can include at least one drive wheel configured to contact a ground surface and move the platform with respect to the ground surface. A drive assist user interface module can be operatively connected to the at least one drive wheel. The drive assist user interface module can be configured to permit an operator of the system to selectively control movement of the at least one drive wheel. The drive assist user interface module can be part of or be attached to an attachment that includes a plate having a top surface. In one configuration, the top surface of the plate can be configured to extend parallel with a top surface of the platform when the attachment is attached to the platform.