A pillow includes a first lobe, a second lobe, and a third lobe extending outwardly from a central node and containing cushioning filling. A closure mechanism extends around perimeter of the first and second lobe. The third lobe is covered by the first and second lobe in a stowed position and not covered in a sleeping position. Portions of the first and second lobe exposed in the stowed position are covered by durable fabric. A Y-shaped inner pillow case may contain the filling and be positioned within the lobes. The filling may include an air bladder with a valve exposed in the stowed position.

A motion pillow according to an embodiment of the present disclosure includes a body, a motion system, a connector, and a valve. The body includes a plurality of airbags provided therein. The motion system includes a pump allowing air to enter and exit the airbags, a sensor measuring air pressures of the airbags, a sound receiver receiving sound from around the body, and a controller controlling operating mode in accordance with measurements of the sensor. The connector connects the airbags and the motion system. The valve opens and closes the connector. When at least one airbag among the plurality of airbags is pressed and air is introduced to the sensor through the connector, the controller is configured to switch the operating mode from standby mode to active mode. Significantly improved convenience and satisfaction of sleep are provided to users.

Various systems and methods relate to an adaptive chair system having (i) a stowed mode in which members of the chair frame are compactly contained within a multi-function bag (MFB), and (ii) a deployed mode in which the multi-purpose chair is configured to transition between at least two seating modes. In an illustrative example, the chair may be provided with an adaptive frame which may be reconfigured to transition between the seating modes. For example, the chair may transition between any of a vertical/upright (chair) mode (e.g., FIG. 8B), a vertical/upright (chair) mode using trek pole handle segment(s) (e.g., FIG. 1C), a low-profile/recon (seat) mode (e.g., FIG. 2B), and a longitudinal/lounge mode (e.g., FIG. 2B). Various embodiments may advantageously provide an adaptive chair system in an ultralight form factor which may fulfill multiple functions including, by way of example and not limitation, seating, sun/rain canopy, footrest, or some combination thereof.

The invention relates to a method for producing a cushion for an orthopedic device, the cushion having at least one fluid-filled volume, wherein the method includes compression molding of a three-dimensional first cushion component made of at least a first material, which is preferably elastic, in a mold that comprises an inner mold and an outer mold, and bonding the first cushion component to at least a second cushion component in such a way that the fluid-filled volume is created.

A telescopic bladder with a noise reduction structure is provided. The telescopic bladder has an opening. The telescopic bladder includes a top plate and a plurality of connected annular bodies extending from a periphery of the top plate toward the opening. The annular bodies have a continuous wavy cross-section. An inner surface of at least some of the annular bodies is formed with at least one protrusion. When the telescopic bladder is applied to a pillow, even if the telescopic bladder is inflated or deflated in the middle of the night, there will be no annoying noise, thereby improving the sleep quality effectively.

A face cushion includes a hollow-out portion located at a central portion of the face cushion; an inflatable portion having an inner peripheral edge located adjacent to the hollow-out portion, an outer peripheral edge, and two slit edges located between the inner and the outer peripheral edge, with an area between the inner and the outer peripheral edge being divided into a first and a second air bag; a slit section formed between the two slit edges; and a plurality of inflating connections separately connected to the first and the second air bag. The first and the second air bag are inflated alternately with gas supplied from a gas supply device to the inflatable body via different pipelines at different time points to produce on the face cushion a facial configuration similar to a patient's face, allowing different parts of the patient's face to contact with the face cushion intermittently.

The present invention relates to a method of operating a smart mattress system enabling alarm control, wherein a user is allowed to transition to a light sleep state before an alarm time set by the user. Furthermore, an air mattress and an air pillow interlock with a user terminal so that the user can easily control the air mattress and the air pillow.

A pillow includes a first lobe, a second lobe, and a third lobe extending outwardly from a central node and containing cushioning filling. A closure mechanism extends around perimeter of the first and second lobe. The third lobe is covered by the first and second lobe in a stowed position and not covered in a sleeping position. Portions of the first and second lobe exposed in the stowed position are covered by durable fabric. A Y-shaped inner pillow case may contain the filling and be positioned within the lobes. The filling may include an air bladder with a valve exposed in the stowed position.

A telescopic bladder with a noise reduction structure is provided. The telescopic bladder has an opening. The telescopic bladder includes a top plate and a plurality of connected annular bodies extending from a periphery of the top plate toward the opening. The annular bodies have a continuous wavy cross-section. An inner surface of at least some of the annular bodies is formed with at least one protrusion. When the telescopic bladder is applied to a pillow, even if the telescopic bladder is inflated or deflated in the middle of the night, there will be no annoying noise, thereby improving the sleep quality effectively.

The present disclosure provides an inflatable bed. The inflatable bed includes a tensioning assembly and an air valve, and further includes an upper piece, a bottom piece, a left piece, a right piece, a front piece, and a rear piece which cooperatively form an inflatable cavity. A left ring frame and a right ring frame are respectively provided on the left and right sides of the upper piece. The tensioning assembly is connected to the inner wall of the inflatable cavity. The air valve is communicated with the inflatable cavity. The inflatable bed of the present disclosure is simple in structure and more economical under the premise of preventing turning sideways.