Described are bed systems including a docking structure defining a first recess and a second recess, a remote to dock into the first recess, and a light integrated into the second recess. The light can move between a docked configuration and an extended configuration. The light can extend out from the second recess and rotate when in the extended configuration. The second recess is aligned with and positioned above the first recess. The first recess has a same width as the second recess, and the first recess has a length substantially longer than the second recess. The remote is oblong and curved at opposite ends. A distal end of the light is oblong-shaped, and the light includes at least one button along a lateral side of the light for turning the light on and off.

Described are bed systems with headboards having a main headboard portion, a left wing attached to a first lateral edge and a right wing attached to a second lateral edge of the main headboard portion, and sound insulation material and insulation supports in each of the main headboard portion and the left and right wings. The insulation supports can be spaced apart to form cavities that can be filled in by the sound insulation material. The sound insulation material can be wool batten insulation. The bed system can also include speakers integrated into the left and right wings that allow a user to play audio, such as white and/or pink noise, to cancel surrounding noise. The bed system can also include microphones and a controller that can drive the speakers to cancel noise detected by the microphones.

A bed has a mattress. A sensor is configured to sense sleep readings of a user sleeping on the bed. An automation controller is configured to transmit the sleep readings to a cloud service. Hardware hosting the cloud service is configured to compare the sleep readings with trend data in order to generate adjustments to the user's sleep environment.

According to one embodiment, a control device includes a user interface device. The user interface device includes an operation receiver that is capable of receiving a command operation for a movable part of the electric furniture. At least one of a brightness and a color of at least a portion of the user interface device changes on the basis of a fluctuation of a first signal. The first signal corresponds to a biological signal that includes at least one of the respiration and the heartbeat of the user of the electric furniture.

An improved mattress FR cap structure incorporating skirting with zones of different friction character. The skirting incorporates a first zone positioned for placement across upper portions of the mattress' vertical sides and a second zone positioned for placement over lower edges of the vertical sides. The first zone forms a first high friction interface with the underlying mattress foam or other material providing substantially stable, fixed positioning between the first zone and the underlying material restricting relative movement. The second zone provides a low friction interface with the underlying mattress foam or other material permitting relative movement between the second zone and the underlying material during compression and/or recovery. The FR cap may also include a third zone positioned for placement adjacent to the second zone for disposition at the underside of the mattress in the final construction and providing a second high friction interface with the underlying material.

A remotely controlled powered chair may include a support frame, a seat pivotally mounted on the support frame, an rotary actuator mounted between the support frame and the seat to drive the seat to move relative to the support frame, a backrest pivotally mounted on the seat, and a linear actuator mounted between the seat and the backrest to drive the backrest to move relative to the seat. Thus, the rotary actuator may be controlled by an electrically control device to drive the seat to pivot relative to the support frame reciprocally in a pendulum manner so that the seat is pivoted relative to the support frame automatically. In addition, the linear actuator may be controlled by the electrically control device to adjust the inclined angle of the backrest so as to provide a comfortable sensation to the user. A remotely controlled powered chair may include a base assembly. A chair frame is supported on the base assembly. An actuator mechanism may communicate with the base assembly and the chair frame, and is operable to actuate the chair frame between first and second positions.

A system including a self-adjusting chair is provided. The system includes a chair that is configured to be adjustable to an occupant. The system also includes a plurality of sensors, wherein each sensor of the plurality of sensors is configured to measure a characteristic of the occupant and to transmit a signal that indicates the characteristic of the occupant. In addition, the system includes a plurality of actuators, wherein each actuator of the plurality of actuators is configured to adjust a property of the chair. Further, the system includes a controller that is configured to receive at least one signal from at least one sensor of the plurality of sensors and to instruct at least one actuator of the plurality of actuators to adjust at least one property of the chair based on at least one characteristic of the occupant.

Body support assembly (1) having a top surface (2) and a spaced away bottom surface (3) defining a cushion volume (4) and defining side walls (5). The air permeability of the top surface (2) is higher than the air permeability of the bottom surface (3). The cushion volume (4) comprises an upper cushion zone (7) and a lower cushion zone (8) and separated by a separation sheet (9). The upper cushion zone (7) and the lower cushion zone (8) comprise of a compressible material (10) which is permeable for air in all directions. The cushion volume (4) further comprises a flow path for air comprising an air inlet (6) in the bottom surface (3), air displacement means (20), a heat exchanger (21), a flow path through the compressible material of the lower cushion zone (8), through openings in the separation sheet (9) and through the compressible material (10) of the upper cushion zone (7) and multiple air outlets as present in the top surface (2).

A mattress and mattress cover assembly, comprising a mattress component, wherein the mattress component includes a first foam layer having a top side and a bottom side; and a second foam layer, wherein the second foam layer is attached to and extends widthwise and lengthwise across the bottom side of the first foam layer; and a covering completely enclosing the mattress component, wherein the covering includes at least one liquid-resistant layer, wherein the at least one liquid-resistant layer is an outer layer comprising elastic fibers; and at least one fire-retardant layer either attached to or formed integrally with the at least one liquid-resistant layer, wherein the at least one fire-retardant layer is an inner layer comprising fire-retardant fibers.

A transport assist equipment assists transport of an object. The transport assist equipment includes a plurality of mecanum wheels, a plurality of motors, a first sensor, and a controller. The plurality of mecanum wheels are attached to the object. The plurality of motors are respectively attached to the plurality of mecanum wheels, and configured to respectively drive the plurality of mecanum wheels. The first sensor detects a force applied to the object. The controller is electrically connected to the first sensor and controls the plurality of motors. The controller drives the plurality of mecanum wheels via the motors so as to propel the object along a direction in which the object receives the force, based on a detection signal of the first sensor.