A movable medical bed system may include a bed body and a power supply apparatus. The power supply apparatus may include an electrical energy receiver and an electrical energy transmitter. The electrical energy receiver is arranged on the bed body. The electrical energy transmitter is configured to be connected to a power source. The bed body is able to move to a working position relative to the electrical energy transmitter. When the bed body is located at the working position, the electrical energy receiver can engage in electrical energy transmission with the electrical energy transmitter without plugging-in. The movable medical bed system helps to make the supply of power more convenient.

A bed apparatus includes: a mattress mounted on a bed body; and, first cells arranged on both left and right sides in a longitudinal direction of the bed body and is configured to change the body position of a patient on the mattress by inflating the first cells alternately. When the first cells on the left and right sides are inflated, and when a difference in pressure between the first cells on the left and right sides has continuously fallen within a decision pressure value range for a decision pressure value continuation time, the body position of the patient is changed, whereas when the difference has not continuously fallen within the pressure value range for the continuation time or when the difference has continuously fallen out of the pressure value range for the continuation time, change of the body position of the patient will not be performed.

The present teachings provide for wheelchair including a control module, manual drive controls, a camera, biometric sensors, and an antenna. The control module includes an autonomous drive module configured to autonomously pilot the wheelchair. The biometric sensors are configured to measure biometric information of a user of the wheelchair.

A surgery table load monitoring system utilizing a base member fixed to a surgery table support. The base member is connected to at least one platform structural member to determine load forces due to the weight of a patient on the platform structured member. Detectors are used to indicate particular stresses and generate a signal which may be employed to disable movement of the surgery table.

A pre/post-tensioning controller system for a wheelchair tie-down and occupant restraint system (“WTORS”) will be a comprehensive energy management system for controlling excessive excursions of a wheeled mobility device during various adverse driving scenarios. The system uses multiple pre-tensioning and post-tensioning events during a front, side, or rear impact crash or rollover scenario—and effectively controls excursions by the tensioning of the WTORS equipment at specific and ideal moments. The system also uses tensioning events on the tie-down equipment during a long duration turn or other aggressive maneuvers. The system may also use tensioning events on the occupant restraints. The energy management system can be adapted for use with traditional four-point tie-downs and newer three- and two-point tie-down systems that incorporate fixed or movable bumpers, as well as compressive-type securement systems, and other systems as well, including docking systems.

Mattresses for human stabilization may include a mass of foam material. A cover including a fabric material may at least partially surrounding the mass of foam material. Head blocks including a foam material may be located proximate to one end of the mattress. The fabric material of the cover may at least partially cover the head blocks, and the head blocks may be foldable relative to the mass of foam material to enable the head blocks to be positioned against lateral sides of a person's head. Human stabilization platforms may include a litter having a surface sized and shaped to support a person thereabove. Straps may be configured to restrain a person's head, the straps having releasable connectors at ends thereof. A track may be located on the surface of the litter, and may be configured to receive the connectors to affix the straps to the litter.

The invention relates to a support arm system (10) for movably holding at least one medical device, including at least one movably supported support arm (18, 20, 22, 24) which is configured to hold the at least one medical device, having at least one load detection device (26) which is configured to detect the respective load data of the support arm system (10) during usage thereof; in particular configured by moving the support arm (18, 20, 22, 24), and which is formed with at least one storage device (46) which is configured to store the detected load data. Further, the invention relates to a method for operating a support arm system (10) and method for designing a support arm system (10).

An electric wheelchair includes a main frame; a driving wheel supported by the main frame; an electric motor disposed on the main frame to drive the driving wheel; a clutch that switches a power transmission path from the electric motor to the driving wheel between an engagement state and a disengagement state; and a clutch operation handle configured to be moved in a predetermined range in an up-down direction. The clutch operation handle is configured so that when the clutch operation handle is stopped at a lowest position of the predetermined range, the clutch is operated so as to be in one of the engagement state and the disengagement state, and when the clutch operation handle is stopped at a highest position of the predetermined range, the clutch is operated so as to be in the other state.

In a mobile stretcher, in order to change the height position of a patient support mounted on a chassis, the chassis geometry is modifiable by a hydraulic drive system. The drive system includes a linear actuator, a pressure supply unit, and a receiving space for hydraulic fluid. A manually actuatable unlocking valve unit directly connects a lifting working chamber of the linear actuator to the receiving space. The valve unit has a control space delimited by a piston element movably guided relative to the housing of the valve unit and which communicates with a lifting attachment, which communicates with the working chamber. The piston element is operatively connected to a valve body interacting with a valve seat of a relief valve between the lifting attachment and a tank attachment communicating with the receiving space. A mechanical actuation input acts on the valve body, with a spring element interposed.

Described herein are multifunctional smart beds and methods of operating thereof. Specifically, a multifunctional smart bed comprises a controller, configured to receive input from various sensors (e.g., load cells positioned in bed legs, thermometers, and/or microphones) and/or user. These inputs are analyzed and used to control various bed components to improve the sleep quality, to monitor users' health, score couple's relationship, and the like. For example, these inputs may be used to control the firmness of different mattress portions, change orientations of the head, torso, and/or leg sections, adjust the light, and the like. In some examples, the smart bed generates a report indicating one or more sleep duration, sleep depth profile, sleep scope, heart rate, breath rate, environment conditions, couple's relationship, and the like. Furthermore, in some examples, a multifunctional smart bed is also configured to control external devices in the same environment, e.g., smart switches, smart thermostats.