Patent Grant
7107642
The invention provides a novel adjustable mattress and pillow system and related methods in which a sensing mat positioned on the top face of a mattress affects microprocessor-controlled optimization of the contour of the mattress and a pillow by pre-selected inflation or deflation of pillow and mattress compartment or compartments based on a user's position. In one embodiment, the novel adjustable mattress and pillow system of the invention provides real time contour optimization through use of a variety of sensing techniques that make the system particularly useful in daily home-use and in environments such as hospital critical care facilities where proper positioning of a user on a mattress and a pillow may prove important to user's health.
Due to the contact shapes of a head and body in contact with pillow and mattress changes with sleeping pose, it is difficult to have a pillow/mattress fit and provide a comfortable support during various sleeping poses, even for a normal healthy person.
It is even worse for a person suffering from chronic back or neck pain; he or she is often is unable to sleep comfortably, and may not be able to recline on a traditional mattress and pillow without great discomfort. Even if a person suffering from such ailments is able to fall asleep, unavoidable movement during sleep can exacerbate an underlying ailment and wake the individual. Similarly, a patient suffering from trauma such as a burn, or recovering from surgery, may suffer great discomfort caused by shifting body and head position on a traditional mattress and pillow. Improper body positioning can cause serious risk to an injured or post-surgical patient, for example, by exacerbating a wound through undesirable rubbing against a mattress or pillow surface or by otherwise creating conditions that may give rise to infection. In neonatal and other critical care settings, improper patient positioning on a mattress can prove life-threatening.
U.S. Pat. No. 6,385,803 (“'803 Patent”) discloses one of many methods or systems that attempt to provide improved means to support a body. The '803 Patent discloses a method and apparatus for supporting the body of a patient. The apparatus disclosed is a support device essentially comprising only at least one closed or controlled-release chamber together with inlet and outlet means by which a filling fluid can be fed in or removed, and an independent control device which is disposed under the support device. The control device comprises filling and emptying means for filling the chamber with filling fluid or for emptying said fluid there from and control means for controlling feeding in and removing the filling fluid. This apparatus and system is understood to measure body penetration into a support chamber and adjust such penetration independent of a user's body position. The system and apparatus of the '803 Patent are understood to use servo control techniques to control the user's body penetration.
U.S. Pat. No. 6,421,858 (“'858 Patent”) discloses a mattress having at least one cushion element which is adapted to be inflated with a pumpable filling medium and a device for regulating the pressure of said filling medium in said cushion element, said device being equipped with a control in which at least one of filling pressure values and at least one arithmetical operation for determining a filling pressure value are predetermined or programmed.
Despite available apparatus and systems, the need continues to exist for a mattress and pillow system and related apparatus that will facilitate real-time optimization of the contour of the mattress and a pillow based on a user's position. The need for such a system and apparatus is particularly acute in the health care field, where currently available beds, mattresses, pillows, or stretchers or examining or surgical tables, may cause great discomfort to a patient. A system that facilitates real-time optimization of the contour of the mattress and a pillow based on a user's position could greatly enhance the safety of patients in neonatal and other critical care settings.
The invention provides an adjustable mattress and pillow system comprising a sensing mat, a mattress and a pillow which adapts to an optimum contour by pre-selected inflation or deflation of pillow and mattress compartment or compartments based on a user's position to provide an optimum support of a user's body, head, and neck. The sensing mat is put on top of the mattress at a position below the pillow where the upper part of the user's body rests on. The sensing mat, for example, an electrically conductive sensing mat having a mat top outer face for receiving and supporting a user's body and a mat bottom outer face in substantial contact with the mattress top face. In one embodiment, the sensing mat is an electrically conductive sensing mat comprising an electrically conductive membrane comprised of an elastomeric material which exhibits a decreasing electrical resistance when compressed. This membrane may be applied to the mat top face or sandwiched between and in electrical contact with the mat top inner face and mat bottom inner face.
The sensing mat is able to differentiate pressures or applied weight per unit area of a user's upper body in different poses. When a user lays flat (face facing upwards), the pressure load on the mat is less than the pressure load on the mat created when the user reclines sideways, also the width of the loaded area of sensing mat when the user lays in a flat position is wider than the loaded area of the sensing mat with the user in sideways position.
This continuous sensing aspect of the electrically conductive sensing mat embodiment of the invention ensures the greatest degree of controlled optimization of the contour of the mattress and a pillow based on a user's position.
Electrically-conductive elastomers useful in the sensing mat include, but are not limited to, elastomeric polymers containing phosphazene groups, e.g., polymer compositions comprising a polynorbonene backbone and pendant cyclotriphosphazene groups. The electrically conductive membrane could also comprise, for example, materials such as Kevlar® impregnated with electrically conductive metals.
The sensing mat can utilize any number of sensing elements to determine, or differentiate between, the poses or positions of the body of an individual during use of the system of the instant invention. For example, the mat can utilize an infrared sensor, an ultrasonic detector, a digital image scanner, an electrically conductive elastomeric membrane or an electrically conductive silicon rubber. In other embodiments, the mat registers change in user position through capacitors, magnets, thermistors, or pressure transducers.
In still another embodiment, the mat comprises an induction system combined with a piece of metal foil situated under the user being supported. Displacement of the metal foil modifies the self-induction coefficient of the induction coil, shifting the resonant frequency of the LC circuit away from the tuning frequency of an oscillator, thereby damping the signal delivered to an amplifier by the oscillator, so as to ensure that the signal is correctly processed and appropriately monitored.
Thus, the mat in one embodiment can comprise a capacitive array which is interconnected with a pumping/control unit under microprocessor control. The pumping/control unit under microprocessor control supplies to the capacitive array a suitable oscillator derived driver current and concurrently senses capacitance value changes within the capacitive array induced through dielectric shifts within the array brought about by the proximity or absence thereof of the user's body mass. The pumping/control unit under microprocessor control generally comprises a power supply, a driver/sensor circuit, a comparator/calibration logic circuit, a system interconnection integrity circuit and an alarm generation circuit. It may also optionally contain a nurse call relay circuit for interconnection to a facilities nurse call system. Further details of the pumping/control unit under microprocessor control are provided hereinafter.
In one embodiment, the driver/sensor circuit of the pumping/control unit under microprocessor control provides and senses a suitable current to the capacitive array located in the mat. The microprocessor control may be controlled by a comparator/calibration logic circuit that continually analyzes and optimizes signals received from and generated by the driver/sensor circuit. In this way, the logic circuit defines capacitive value parameters which it interprets to indicate whether a user is in close proximity to the capacitive array. In such manner, the logic circuit determines the position of a user on a mat.
In an embodiment of the invention useful in hospitals and other health care institutions, and in particular in neonatal or other critical care applications, if the capacitive value change of the mat remains at a level indicative of a user being in an undesirable position on the mat, the logic circuit would, after a suitable pre-programmed time delay, instruct an alarm circuit to activate. This alarm activation may consist solely of audible and/or visible alarms on or within the pumping/control unit or may be directed to a medical facility's nurse call system through an appropriate interface relay circuit contained either within, or remote to, the pumping/control unit.
In addition to the above described functions, in one embodiment, the microprocessor control logic circuit receives continuous data from a pumping/control unit system interconnection integrity circuit about the continuity of connection between the pumping/control unit and the capacitive sensor array and, where appropriate, between the pumping/control unit and a medical facility's nurse call system.
The logic circuit may also, if appropriate, continuously monitor the entire system during utilization for service faults and subsequently generate appropriate alarms.
In still other embodiments of the invention, the system uses a proximity induced non-compressive dielectric shift sensing mechanism, and thus reliably detects the presence and position of a user on the mat, with minimal discomfort to the user and with a greatly extended sensor element service life.
There are one or more inflatable mattress compartments located within the mattress, the compartments being: (1) positioned between the top face and bottom face of the mattress; (2) connected to a fluid reservoir for receiving fluid; and (3) provided with at least one fluid vent under microprocessor control for discharge of fluid. These inflatable compartments can: (1) take any shape; (2) and be arranged in any number of (vertical or horizontal) positions; and be made of any number of materials, depending upon the intended environment of use of the system. For example, antimicrobial or antibacterial preservatives could be coated on the compartments to avoid the risk of contamination if the system is used in a medical environment. Additionally, anti-static coatings may be applied to the compartments to reduce any risk associated with shock. Compartment shape can also be customized to suit the particular needs of a category of user: for example, certain configurations may prove better suited for children, the elderly, or patients suffering from certain illnesses or injuries.
A pillow is positioned on the top face of the mattress and adapts to an optimum contour for support of a user's head and neck. The pillow comprises a top face for supporting a user's head and neck and a bottom face which is substantially in contact with the mat top face.
The pillow has one or more inflatable pillow compartments located within the pillow, the compartments being: (1) positioned between the top face and bottom face of the pillow; (2) connected to a fluid reservoir for receiving fluid; and (3) provided with at least one fluid vent under microprocessor control for discharge of fluid. The pillow compartment is as versatile as the mattress compartment in terms of design and the entire aforementioned mattress compartment configuration and material examples apply equally to the pillow compartment.
The pillow may or may not be affixed to the top face of the mattress.
The mattress and pillow compartments of the instant invention may be surrounded or packed in a cushioning material such as polymeric foam, man made or natural fiber, to provide additional support and comfort to the user.
As mentioned, the system of the instant invention further comprises a pumping/control unit under microprocessor control that is positioned remotely from the mattress and pillow. The pumping/control unit may comprise any one of a number of devices useful for the conveyance of fluid, e.g., a pump or compressor, and is connected to a fluid reservoir and the inflatable mattress compartments and the inflatable pillow compartments for transmitting fluid from the reservoir to one or more of those compartments. “Positioned remotely” as used above is a relative term; in one embodiment of the instant invention discussed hereinafter, the pumping/control unit, fluid reservoir, pressure sensitive mattress, and pillow are all mounted on the same frame.
As indicated previously, the microprocessor control used in the instant invention: (1) is in communication with, e.g., in electrical contact with, the mat for receiving and processing signals, e.g., electrical signals from the mat which vary in relationship to the pressure exerted on the mat's electrically conductive membrane as the position of the user shifts; (2) processes those signals pursuant to preprogrammed instructions; and (3) transmits an output signal to the pumping/control unit and fluid vents. On the basis of the output signal, fluid is either transmitted from the reservoir by the pumping/control unit to one or more of the inflatable mattress compartments or inflatable pillow compartments, or is discharged from one or more of the inflatable mattress compartments or inflatable pillow compartments by a fluid vent to optimize the contours of the mattress and pillow relative to the user's position on the mattress and pillow.
In another embodiment of the claimed invention, the pumping/control unit is connected to a fluid reservoir and the inflatable mattress compartments and the inflatable pillow compartments for transmitting fluid from the reservoir to one or more of those compartments and for discharging fluid from one or more of those compartments to the reservoir.
The fluid utilized in the instant invention can be any number of suitable liquids or gases, including water, air, and inert gas mixtures.
These and other features of the instant invention are described in greater detail in the following detailed description.
As shown in
Referring again to
Pillow 5 is positioned on top face 1A of mattress 1 and adapts to an optimum contour for support of a user's 100 head and neck as described hereinafter. Pillow 5 has a top face 5A for supporting a user's head and neck and a bottom face 5B which is substantially in contact with pressure sensitive mattress top face 1A. Pillow 5 has one or more inflatable pillow compartments 6 located within pillow 5, compartments 5 being: (1) positioned between top face 5A and bottom face 5B of pillow 5; and (2) connected to fluid reservoir 10 by conduits 7 and 9 through pumping/control unit 8 under control of control device 8A for receiving and discharging fluid. Pillow 5 may optionally be affixed to mattress top face 1A through, for example, hook and loop fasteners (e.g., Velcro®), snaps, or other well-known means. Pillow compartments 6 can have any number of shapes.
In the illustrated embodiment of
As mentioned, “positioned remotely” as used above is a relative term; in another embodiment of the instant invention shown in
Control device 8A comprises a microprocessor which is programmed to control flow of fluid to and from compartments 3 and 6 by regulation of fluid flow through conduit valves 4A, 7A, and 9A and regulation of fluid flow conditions in pumping/control unit 8, in response to electrical signals conveyed from mat 2 through electronics signal wires 2C to control device 8A as described hereinafter. Fluid flow control can be achieved in the system of the instant invention through a variety of standard process control techniques. For example, control device 8A can function as a mass flow controller in which a microprocessor has sensing and signal processing elements in communication with pumping/control unit 8 and valve drives 4B, 7B, and 9B that operate valves 4A, 7A, and 9A to control the mass flow rate of fluid. The microprocessor can be preprogrammed with a set point established by an external input supplied by the user or a third party in order to fix a desired fluid flow rate, and hence mattress 1 and pillow 5 contour, in response to certain signals transmitted from mat 2 through electronics signal wires 2C.
In the embodiment illustrated in
The microprocessor used in the instant invention can be a microprocessor having a central processing unit or CPU for a digital processor, which is usually contained in a single semiconductor integrated circuit, or “chip” fabricated by MOS/LSI technology. For example, the microprocessor could be a single-chip 8-bit CPU including a parallel ALU, registers for data and addresses, an instruction register and a control decoder, all interconnected using the von Neumann architecture and employing a bidirectional parallel bus for data, address and instructions. The microprocessor could also be a single-chip “microcomputer” type device which contains a 4-bit parallel ALU and its control circuitry, with on-chip ROM for program storage and on-chip RAM for data storage, constructed in the Harvard architecture. The microprocessor can also be a device employing external memory for program and data storage, or a device with on-chip ROM and RAM for program and data storage. The microprocessor could therefore be a microcomputer. Since the terms “microprocessor” and “microcomputer” are often used interchangeably in the art, however, it should be understood that the use of one of the other of these terms in this description should not be considered as restrictive as to the features of this invention.
The microprocessor can be selected from general-purpose microprocessors and special-purpose micro-computers/microprocessors. General-purpose microprocessors, such as the M68020 manufactured by Motorola, Inc. are designed to be programmable by the user to perform any of a wide range of tasks, and are therefore often used as the central processing unit in equipment such as personal computers. In contrast, special-purpose microcomputers are designed to provide performance improvement for specific predetermined arithmetic and logical functions for which the user intends to use the microcomputer. By knowing the primary function of the microcomputer, the designer can structure the microcomputer in such a manner that the performance of the specific function by the special-purpose microcomputer greatly exceeds the performance of the same function by the general-purpose microprocessor regardless of the program created by the user.
Therefore, a user or third party (e.g., a physician or a nurse) in one embodiment of the instant invention can program a personal computer which functions as part of control device 8A to affect microprocessor-controlled optimization of the contour of the mattress and a pillow based on a user's position.
Control device 8A is in electrical contact with electrically conductive sensing mat 2 through electronics signal wires 2C for receiving and processing electrical signals from mat 2 through electrical contact with flexible PCB 2R shown in
In one illustrative embodiment, electrically conductive sensing mat 2 comprises an induction system combined with a piece of metal foil situated under the user, and wherein displacement of the metal foil modifies a self-induction coefficient of an induction coil, thereby shifting the resonant frequency of an LC circuit away from the tuning frequency of an oscillator and damping the signal delivered to an amplifier by the oscillator to ensure that the signal is correctly processed and appropriately monitored.
In another illustrative embodiment, electrically conductive sensing mat 2 comprises a capacitive array which is interconnected with the pumping/control unit under microprocessor control, and wherein the a pumping/control unit under microprocessor control supplies to the capacitive array a suitable oscillator derived driver current and concurrently senses capacitance value changes within the capacitive array induced through dielectric shifts within the array brought about by the proximity or absence thereof of the user's body mass.
In another illustrative embodiment, the pumping/control unit under microprocessor control comprises a power supply, a driver/sensor circuit, a comparator/calibration logic circuit, a system interconnection integrity circuit and an alarm generation circuit.
In another illustrative embodiment, the pumping/control unit under microprocessor control comprises a nurse call relay circuit for interconnection to a facilities nurse call system.
In still another illustrative embodiment, a system of the invention further comprises a proximity-induced non-compressive dielectric shift sensing mechanism.
Again with reference to
Referring to
The aforementioned examples of embodiments of the instant invention are illustrative only and in no way limit the full scope of the invention as claimed.
The instant invention claims priority from U.S. Provisional Patent Application Ser. No. 60/454,000 filed Mar. 12, 2003.
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