A controller for a furniture drive includes an operating device which includes a speech controller. The speech controller includes a speech control subunit operatively connected to an adjustment drive, and a microphone interacting with the speech control subunit.

A patient support apparatus for traversing objects supported on ground surfaces. The patient support apparatus comprises a patient support deck, and a base to support the patient support deck from the ground surface. At pair of caster wheel assemblies spaced from each other are coupled to the base for pivoting movement about respective pivot axes cooperating to define a reference plane. A frame guard coupled to the base defines first and second ramp surfaces each disposed at an angle relative to the reference plane. The first ramp surface is arranged to engage objects before they contact one or more of the caster wheels when the patient support apparatus moves in a first direction. The second ramp surface is arranged to engage objects before they contact one or more of the caster wheels when the patient support apparatus moves in an opposite, second direction.

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 firmness of different mattress portions, change orientations of 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, breadth 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.

A chair for particular use in clinical or hospital environments has a frame to which a support material is secured. The support material may form a chair back and/or a seat for the chair to provide support to the chair occupant. The support material may be made from a textile of interwoven strands wherein some of the interwoven strands include copper containing particles such as copper iodide or copper oxide within the textile fibers.

A flexible mat may be configured to be placed between a patient and a patient support apparatus. The flexible mat may be used for determining a condition of a patient based on LC resonator data. The flexible mat may include a set of one or more LC resonators. Each LC resonator may include a capacitor and an inductor and may be configured to oscillate at a frequency associated with a present capacitance of the capacitor. The flexible mat may also include circuitry configured to measure an oscillation frequency of at least one of the LC resonators. The circuitry may also be configured to convert the measured oscillation frequency to digital frequency data which may be indicative of the measured oscillation frequency. The circuitry may also be configured to determine, based on the frequency data, at least one of a position, a heart rate, or a respiration rate of the patient.

A method including a remote device establishing an encrypted communication link with a user equipment, where the user equipment is associated with a wheelchair, where the encrypted communication link is established based at least partially upon a wheelchair identifier transmitted by the remote device which identifies the wheelchair; transmitting an access level by the remote device to an access controller; and receiving data by the remote device from the wheelchair via the use equipment and a network, where the data received by the remote device is limited corresponding to the access level of the remote device transmitted to the access controller.

The present disclosure provides various systems and methods for assisting with lower limb movement. An exemplary system can include a plurality of wearable modules and a controller. Each of the plurality of wearable modules can include a stimulator and a sensor. The controller can be configured to detect a desired activity based on data from the sensors on the wearable modules. The controller can be further configured to cause the stimulator to provide electrical stimulation to assist with the desired activity.

The present invention relates to a fall prevention safety wheelchair brake device, and more particularly, in a wheelchair having a safety bar for preventing a safety accident due to a fall while moving the wheelchair, to a fall prevention safety wheelchair brake device in which a brake is locked when the safety bar is not fastened, and the brake is switched from a locked state to an unlocked state when the safety bar is fastened.

A patient support apparatus pneumatic system may include a mattress defining an interior and a pneumatic enclosure in fluid communication with the interior and comprising an inlet and an outlet. A blower may be in fluid communication with the interior and the pneumatic enclosure. A pressure sensor may be configured to detect a pressure at the outlet. A controller may be configured to monitor a speed of the blower and the pressure at the outlet for detecting at least one of an intake blockage condition and an exhaust blockage condition.

A body waste collection system for bedridden or chair-bound patients. A waste entry port may interface with a resting surface of the bed or chair by way of a funnel that terminates at the resting surface. A collection unit may be fluidly coupled to the waste entry port by a flexible conduit system. The collection unit may include a temperature gauge, a volume measure, a sample port, and an odor removal port. Once the bedridden or chair-bound patient has assumed a release position along the resting surface defined by the waste entry port, no other lifting or movement of the patient is needed to collect their body waste in the collection unit, which can utilize the integrated hardware.