Knitted fire barrier fabrics for use in forming a flame retardant article having a core include, for example, a plurality of flame-retardant yarns formed non-uniformly around a circumference of a knitting textile cylinder in a knitting process so as to define the knitted fire barrier fabric having at least one differential zone of material in a longitudinal direction of the knitting textile cylinder, and wherein the knitted fire barrier fabric being disposable on the core so that the at least one differential zone of material of the knitted fire barrier fabric providing a differential protective capacity to at least one selected portion of the flame retardant article.

A body support cushion is provided with layered foam which receives airflow and allows passage in predefined areas through the body support cushion. Additionally, a cover is provided including a spacer fabric that allows air movement from the body support cushion to improve ventilation of the user of the cushion.

A mattress including a stretchable flame-retardant textile cap incorporating a top panel of flame retardant material operatively connected to a stitch-bonded flame retardant textile skirting with machine direction stretch and recovery properties disposed over a resilient mattress core to provided flame barrier protection to the mattress core.

Provided herein is a new fire barrier material composed of flame retardant (FR) cellulosic fiber(s) and one or more of an antimicrobial (AM) cellulosic fiber and an untreated cellulosic fiber(s). The fire barrier material may be a fabric woven or knitted from the yarn containing the FR cellulosic fiber(s) and the one or more of AM cellulosic fibers and untreated cellulosic fibers. When AM cellulosic fibers are combined with FR treated cellulosic fibers, the fire barrier material has the dual features of flame retardancy and antimicrobial properties. The fire barrier material may also be a nonwoven, and in preferred embodiments optionally includes a binder fiber. The FR cellulosic fiber contains FR chemical(s) or FR compound(s) that have a melting point or decomposition temperature at 400 C. (752 F.) or below. The FR performance of the new nonwoven provided herein is comparable to the conventional FR nonwoven (FR cellulosic fiber/binder fiber), but has advantages in cost effectiveness, as well as antimicrobial properties.

A bed system includes microclimate control capabilities for providing quality sleep experience. The bed system can include a microclimate control subsystem configured to supply conditioned air (e.g., heated or cooled air) to a mattress, or draw ambient air from the mattress, to achieve a desired temperature at the top of the mattress. Utilizing supply of conditioned air to provide air at desired temperature to the mattress system, or utilizing air suction to drain heat away from the mattress system, can provide precise microclimate control at the mattress, thereby permitting conformable sleep.

A method and bed system for controlling a mattress climate-control system based on a thermal event. The bed system includes a mattress, a mattress climate-control system, a mechanical thermal detector, and a controller. The mattress climate-control system controls a climate at the mattress. The mechanical thermal detector is positioned at the mattress. A condition of the mechanical thermal detector changes in response to a thermal event at the mattress. The controller is connected to the mattress climate-control system. The controller perform operations including detecting the condition of the mechanical thermal detector and operating the mattress climate-control system based on the condition of the mechanical thermal detector.

Reinforcement straps are used to hold a mattress system in place and keep it from bowing outwards when used. The mattress system can include a layer and a rail structure attached to the layer. The layer can have a layer top and a layer bottom opposite to the layer top. The layer can extend between a first layer edge and a second layer edge.

A bed system includes microclimate control capabilities for providing quality sleep experience. The bed system can include a microclimate control subsystem configured to supply conditioned air (e.g., heated or cooled air) to a mattress, or draw ambient air from the mattress, to achieve a desired temperature at the top of the mattress. Utilizing supply of conditioned air to provide air at desired temperature to the mattress system, or utilizing air suction to drain heat away from the mattress system, can provide precise microclimate control at the mattress, thereby permitting conformable sleep.

Described is a rollup evacuation sled that includes a bottom sheet, a foam mattress disposed above the bottom sheet, and a support sheet disposed above the mattress. A margin stack including the bottom sheet and the support sheet forms a sandwiched margin left side and a sandwiched margin right side. The sled may further include a plurality of spinal boards disposed between the bottom sheet and the mattress in the upper section of the bottom sheet. Wheel assemblies are mounted on each spinal board. The sled further includes a foot pouch coupled to the sandwiched margin left and right sides and dimensioned to substantially enclose feet and calves of a person lying on the support sheet. The foot pouch is configured to store a stack including the bottom sheet, mattress and the support sheet, when the stack is rolled up along a longitudinal direction from the head end.

A bed system includes microclimate control capabilities for providing quality sleep experience. The bed system can include a microclimate control subsystem configured to supply conditioned air (e.g., heated or cooled air) to a mattress, or draw ambient air from the mattress, to achieve a desired temperature at the top of the mattress. Utilizing supply of conditioned air to provide air at desired temperature to the mattress system, or utilizing air suction to drain heat away from the mattress system, can provide precise microclimate control at the mattress, thereby permitting conformable sleep.