An anti-bedsore bed may comprise a bed unit, a first bed body, and a second bed body. The bed unit has a first mattress, and a bottom portion is coupled on a bottom surface thereof. Moreover, the bottom portion comprises six supporting units evenly arranged into three sets at positions corresponding to a user's upper, middle and lower back, and each of the supporting units has a sliding block moveably mounted on an upper surface of the bottom portion. Furthermore, each of the sliding blocks has a supporting rod, and an abutting unit is pivotally connected to an upper end of the supporting rod. The supporting rods are configured to move upwardly in a preset time interval, and the abutting units are adapted to uplift a user's body to detach from the first mattress for a designed time, thereby achieving the anti-bedsore effect.

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.

An actuating system including at least one actuation section that includes a plurality of actuating supports. Each of the actuating supports includes a shaft assembly and configured to be actuated individually. The shaft assembly of each of the plurality of actuating supports is configured to translate between a first position and a second position. In the first position an actuated actuating support is aligned with the remaining of the plurality of actuating supports and in the second position the actuated actuating support is misaligned with the remaining of the plurality of actuating supports.

A smart powered rocking bed is disclosed comprising a plurality of vertical and horizontal actuators in contact with a rocking frame configured to receive the rocking bed, the electronic actuators configured to act together to rock the bed in three dimensions. The smart powered rocking bed also includes a digital processor configured to electrically drive the actuators in a plurality of predetermined multi-directional and simultaneous ocean-like motions over a period of time provided for a user's choice. The smart powered rocking bed additionally includes a linkage configured to connect the rocking frame to the actuators and mechanically provide the multi-directional and simultaneous ocean-like motions in the three dimensions over time as chosen by the user. A smart powered rocking bed system further includes a health care database, a discrete personal digital device such as a cell phone and health care telemetry sensors placed on or in a user thereof.

The sleeping-posture-control bed system includes a bed floor including a back-lifting portion for lifting the user's back, a bed-floor support body supporting the bed floor, and a back-lifting driver for lifting the head side of the back-lifting portion. The back-lifting portion includes a back-receiving surface and a head-receiving surface tiltable at different angles. The back-lifting driver lifts the back-receiving surface and the head-receiving surface, satisfying Mathematical Formula (1):
0°<θx≦70°,−45°≦θy<0°, and −30°≦θx+θy  (1) where θx is the tilt angle of the back-receiving surface when tilted, and the tilt angle of the back-receiving surface when the back-receiving surface is not lifted is set to be 0°; and θy is the tilt angle of the head-receiving surface when the angle of an extended line of the back-receiving surface at the tilt angle θx is referred to as 0°.

The present disclosure is related to a bed assembly. Specifically, the present disclosure relates to a bed assembly that is compatible with a traditional consumer bed and can enhance the traditional consumer bed so it provides features of a traditional hospital bed. The bed assembly of the present disclosure may include pneumatic components to move portions of the bed assembly.

A pressure sore prevention mattress is provided alternating pressure points on the body of an occupant that is easily transformable between two stable configurations. The four-layer mattress construction has a top foam pad, a webbing layer, a dynamic layer of deformable panels trapezoid-shaped four-bar mechanisms that deform to produce an undulating pattern of peaks, and a base. Panel geometry can determine peak height. The mattress has a spatially hollow geometry that allows natural air convection through the breathable top foam pad to enable drying of moisture as well as the use of forced air convective drying or cooling. The mattress can be transformed from one configuration to the other while the occupant is on the mattress.

A support cushion liner includes a liner body having a cavity disposed between an outer layer and an inner layer and a plurality of artificial muscles disposed in the cavity of the liner body. Each of the plurality of artificial muscles include a housing having an electrode region and an expandable fluid region, a dielectric fluid housed within the housing, and an electrode pair positioned in the electrode region of the housing. The electrode pair includes a first electrode fixed to a first surface of the housing and a second electrode fixed to a second surface of the housing. The electrode pair is actuatable between a non-actuated state and an actuated state such that actuation from the non-actuated state to the actuated state directs the dielectric fluid into the expandable fluid region, expanding the expandable fluid region thereby applying pressure to the outer layer of the liner body.

The present invention provides the bed robot apparatus in which a lying object, including a person such as a patient, a disabled person, etc. can be shifted to another apparatus without changing a lying state and the apparatus autonomously communicates with another apparatus so as to collaborate depending on the situation of the object. Specifically, according to the feature of the present invention, a bed robot apparatus comprising: a mattress partitioned into positions corresponding to body parts of a user in a longitudinal direction; and a porous flexible sheet reciprocating in a lateral direction on the upper surface of the mattress for each divided upper plate is provided. The bed robot apparatus of the present invention can autonomously execute all functions through an autonomous execution unit.

A method and system for patient monitoring, the system comprising a surveillance camera configured to generate a plurality of frames showing an area in which a patient in a bed is being monitored, and a computer system comprising memory and logic circuitry configured to determine bed rails positions of the bed, identify a position of the patient, and generate signals that control the bed rails of a bed based on the bed rails positions and the position of the patient.