Exemplary embodiments of an improved water mat system comprise a plurality of polymeric, closed-cell foam panels, each of the plurality of panels taking any suitable shape and defining a top surface and a bottom surface. A plurality of hinge components are configured and placed to connect the plurality of panels and operable to transition the water mat system between a deployed state and a stored state. When the water mat system is in the deployed state the plurality of panels are positioned in an end-to-end arrangement such that the top surfaces of the panels collectively define a substantially common plane (i.e., the panels are laid out end-to-end). When the water mat system is in the stored state the top surface of a first one of the plurality of panels is juxtaposed to the bottom surface of a second one of the plurality of panels (i.e., the panels are stacked).

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 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.

An air system for a bed can include a layer assembly having a head end, a foot end, and first and second sides, with a head portion near the head end, a foot portion near the foot end, and a middle portion between the head portion and the foot portion, the layer assembly. The layer assembly can have a spacer layer comprising spacer material configured to allow for air flow through the spacer material and a cover comprising a cover top layer and a cover bottom layer. The air system can have a distribution manifold that is substantially fan-shaped with a plurality of ribs defining channels and/or is positioned above the cover bottom layer and under the spacer layer. The air system can have first and second flaps with first and second retention features extending from the head and foot ends of the air layer.

An air system for a bed can include a layer assembly having a head end, a foot end, and first and second sides, with a head portion near the head end, a foot portion near the foot end, and a middle portion between the head portion and the foot portion, the layer assembly. The layer assembly can have a spacer layer comprising spacer material configured to allow for air flow through the spacer material and a cover comprising a cover top layer and a cover bottom layer. The air system can have a distribution manifold that is substantially fan-shaped with a plurality of ribs defining channels and/or is positioned above the cover bottom layer and under the spacer layer. The air system can have first and second flaps with first and second retention features extending from the head and foot ends of the air layer.

An in-bed haptic device may include an array of actuation cells. Actuation cells of the array of actuation cells may be configured to actuate (e.g., expand, contract, or otherwise change shape) in a predetermined sequence to provide haptic outputs. The in-bed haptic device may be configured to be placed beneath a user during use, for example between a user and a mattress. The haptic outputs may be provided to help a user relax, to move and/or wake a user, to indicate outputs, alerts, or notifications at the in-bed haptic device or another electronic device, or the like.

An in-bed haptic device may include an array of actuation cells. Actuation cells of the array of actuation cells may be configured to actuate (e.g., expand, contract, or otherwise change shape) in a predetermined sequence to provide haptic outputs. The in-bed haptic device may be configured to be placed beneath a user during use, for example between a user and a mattress. The haptic outputs may be provided to help a user relax, to move and/or wake a user, to indicate outputs, alerts, or notifications at the in-bed haptic device or another electronic device, or the like.

Shear-reduction cushioning devices are provided for the prevention of shear related wounds. Cushioning devices include upper and lower cushioning layers that contact each other through at least one internal shear reduction layer provided between the cushioning layers and extending over a shear reduction region, such that dynamic relative translation of the two cushioning layers is permitted within the shear reduction region while absorbing friction and shear internally. The interface between the cushioning layers (where the shear reduction layer is provided) may be angled relative to an external surface of the cushioning device. The cushioning layers may be attached or attachable to one another beyond the shear reduction region, to limit an amount of relative translation of the cushioning layers and to re-center or reset the cushioning layers after use.

Shear-reduction cushioning devices are provided for the prevention of shear related wounds. Cushioning devices include upper and lower cushioning layers that contact each other through at least one internal shear reduction layer provided between the cushioning layers and extending over a shear reduction region, such that dynamic relative translation of the two cushioning layers is permitted within the shear reduction region while absorbing friction and shear internally. The interface between the cushioning layers (where the shear reduction layer is provided) may be angled relative to an external surface of the cushioning device. The cushioning layers may be attached or attachable to one another beyond the shear reduction region, to limit an amount of relative translation of the cushioning layers and to re-center or reset the cushioning layers after use.

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.