Abstract: A bed is provided. The bed may include a lift system which raises and lowers a support deck of the bed. The lift system may include multiple individually actuatable lift systems. The bed may include a powered bed mover system.

Abstract: A patient support is provided. The patient support may include a plurality of inflatable members. The plurality of inflatable members may include a core including a resilient material. The patient support may be controlled with a first controller positioned within an envelope of the patient support. The patient support may include a detector to detect when an external controller is coupled to the patient support, the patient support being controlled by the second controller when the second controller is present.

Abstract: A bed is provided. The bed may include a lift system which raises and lowers a support deck of the bed. The lift system may include multiple individually actuatable lift systems. The bed may include a powered bed mover system.

Abstract: The present disclosure relates to a bidirectional valve design that provides for more rapid deflations/evacuation of fluid flow and in one example includes a valve body, a spindle piston movably coupled in a bore of the valve body and an electronically controllable motor that moves the spindle valve between a fluid evacuation position and a fluid fill position. In one example, the spindle piston includes piston structures on ends of a threaded rod. In another example, a mattress system is disclosed that employs the valve and a fluid source to provide quick evacuation of air from a patient support. In another example, the valve is coupled to an alternating pressure block valve which is then coupled to a patient support.

Abstract: A bed is provided. The bed may include a lift system which raises and lowers a support deck of the bed. The lift system may include multiple individually actuatable lift systems. The bed may include an expandable support deck. The bed may include a powered caster braking system.

Abstract: A bed is provided. The bed may include a lift system which raises and lowers a support deck of the bed. The lift system may include multiple individually actuatable lift systems. The bed may include a powered bed mover system.

Abstract: A patient support is provided. The patient support may include a plurality of inflatable members that raise or lower portions of the patient support based on the status of a valve assembly. The patient support may also include a plurality of inflatable members positioned at a foot end of the patient support to support lower legs of a patient including their heels. Another valve assembly is provided to control a bleed rate of air from the heal bladders.

Abstract: The present disclosure relates to a bidirectional valve design that provides for more rapid deflations/evacuation of fluid flow and in one example includes a valve body, a spindle piston movably coupled in a bore of the valve body and an electronically controllable motor that moves the spindle valve between a fluid evacuation position and a fluid fill position. In one example, the spindle piston includes piston structures on ends of a threaded rod. In another example, a mattress system is disclosed that employs the valve and a fluid source to provide quick evacuation of air from a patient support. In another example, the valve is coupled to an alternating pressure block valve which is then coupled to a patient support.

Abstract: A bed is provided. The bed may include a lift system which raises and lowers a support deck of the bed. The lift system may include multiple individually actuatable lift systems. The bed may include an expandable support deck. The bed may include a powered caster braking system.

Abstract: A sonic percussion therapy system includes a patient support apparatus and a control module. The sonic percussion structure is attached to the inflatable cell so that the sonic percussion structure moves in response to movement of the inflatable cell. The control module includes a sonic percussion control module and a position control module. The sonic percussion control module independently controls frequency and/or intensity of at least one of the plurality of sonic percussion structures. The position control module selectively raises and lowers at least one of the plurality of sonic percussion structures with respect to a patient surface.

Abstract: The present disclosure relates to a bidirectional valve design that provides for more rapid deflations/evacuation of fluid flow and in one example includes a valve body, a spindle piston movably coupled in a bore of the valve body and an electronically controllable motor that moves the spindle valve between a fluid evacuation position and a fluid fill position. In one example, the spindle piston includes piston structures on ends of a threaded rod. In another example, a mattress system is disclosed that employs the valve and a fluid source to provide quick evacuation of air from a patient support. In another example, the valve is coupled to an alternating pressure block valve which is then coupled to a patient support.

Abstract: An air distribution support surface product includes a vapor permeable material such as a sheet of breathable material, a fluid resistant material, such as a sheet of waterproof material and an intermediate fluid passing material interposed between the vapor permeable material and the fluid resistant material to form a plurality of chambers. One of the chambers serves as a type of fluid retention chamber and another chamber serves as a type of fluid loss chamber. A fluid intake opening may be provided to allow fluid, such as air, to inflate the chambers. In one example, both of the chambers share the intermediate fluid passing material. As such, the fluid retention chamber is formed by the fluid resistant material and the intermediate fluid passing material. The fluid loss chamber is formed by the vapor permeable material and the intermediate fluid passing material.

Abstract: A patient position apparatus includes a plurality of sensing conductors and a control module operatively coupled to the sensing conductors. The sensing conductors are arranged along a substantially planar surface. The sensing conductors provide sensing information in response to a patient being within proximity of the sensing conductors. The control module selectively adjusts fluid pressure of at least one inflatable cell in response to the sensing information.

Abstract: A sonic percussion therapy system includes a patient support apparatus and a control module. The sonic percussion structure is attached to the inflatable cell so that the sonic percussion structure moves in response to movement of the inflatable cell. The control module includes a sonic percussion control module and a position control module. The sonic percussion control module independently controls frequency and/or intensity of at least one of the plurality of sonic percussion structures. The position control module selectively raises and lowers at least one of the plurality of sonic percussion structures with respect to a patient surface.

Abstract: A patient position apparatus includes a plurality of sensing conductors and a control module operatively coupled to the sensing conductors. The sensing conductors are arranged along a substantially planar surface. The sensing conductors provide sensing information in response to a patient being within proximity of the sensing conductors. The control module selectively adjusts fluid pressure of at least one inflatable cell in response to the sensing information.

Abstract: An inflatable cushion cell has first and second inflatable compartments. Each inflatable compartment is defined by at least one diagonal seal structure. In addition, each inflatable compartment also has at least one fluid opening. In one embodiment the diagonal seal structure is offset from opposite corners of the inflatable cushion cell. In one embodiment patient support system includes a plurality of inflatable such cushion cells are located within a frame. In one embodiment a pressure control system is used control the inflation of the first and second inflatable compartments. In one embodiment a method is used to move a patient in an inflatable patient support system, such as a support system that employs an inflatable cushion cell with a diagonal seal structure.

Abstract: An air distribution support surface product includes a vapor permeable material such as a sheet of breathable material, a fluid resistant material, such as a sheet of waterproof material and an intermediate fluid passing material interposed between the vapor permeable material and the fluid resistant material to form a plurality of chambers. One of the chambers serves as a type of fluid retention chamber and another chamber serves as a type of fluid loss chamber. A fluid intake opening may be provided to allow fluid, such as air, to inflate the chambers. In one example, both of the chambers share the intermediate fluid passing material. As such, the fluid retention chamber is formed by the fluid resistant material and the intermediate fluid passing material. The fluid loss chamber is formed by the vapor permeable material and the intermediate fluid passing material.

Abstract: An inflatable cushion cell has first and second inflatable compartments. Each inflatable compartment is defined by at least one diagonal seal structure. In addition, each inflatable compartment also has at least one fluid opening. In one embodiment the diagonal seal structure is offset from opposite corners of the inflatable cushion cell. In one embodiment patient support system includes a plurality of inflatable such cushion cells are located within a frame. In one embodiment a pressure control system is used control the inflation of the first and second inflatable compartments. In one embodiment a method is used to move a patient in an inflatable patient support system.

Abstract: An inflatable cushion cell has first and second inflatable compartments. Each inflatable compartment is defined by at least one diagonal seal structure. In addition, each inflatable compartment also has at least one fluid opening. In one embodiment the diagonal seal structure is offset from opposite corners of the inflatable cushion cell. In one embodiment patient support system includes a plurality of inflatable such cushion cells are located within a frame. In one embodiment a pressure control system is used control the inflation of the first and second inflatable compartments. In one embodiment a method is used to move a patient in an inflatable patient support system.

Abstract: An inflatable cushion cell has first and second inflatable compartments. Each inflatable compartment is defined by at least one diagonal seal structure. In addition, each inflatable compartment also has at least one fluid opening. In one embodiment the diagonal seal structure is offset from opposite corners of the inflatable cushion cell. In one embodiment patient support system includes a plurality of inflatable such cushion cells are located within a frame. In one embodiment a pressure control system is used control the inflation of the first and second inflatable compartments. In one embodiment a method is used to move a patient in an inflatable patient support system.