Support surfaces for a bed

BACKGROUND AND SUMMARY OF THE INVENTION
The present invention relates to a bed having modular therapy and support surfaces. More particularly, the present invention relates to a hospital bed having an on-board air handling unit and electrical communication network capable of connecting to and controlling a plurality of different modular air therapy and support surfaces for providing a plurality of different therapies or treatments to a patient.
The present invention provides a plurality of different air therapy and support surfaces, all of which can be connected to the bed to provide a complete therapy line that is rapidly installed or exchanged on demand as census or diagnostic population varies. In an acute care environment, a hospital typically needs decubitus prevention, decubitus treatment (stage one and two minimum), pulmonary therapies including rotation therapy and percussion and vibration therapy, and venous compression therapy capabilities.
The modular therapy and support surface design of the present invention allows several air support surfaces and air therapy devices to be driven by a common air source, a common graphical interactive display device, and a distributed communication network. The modular therapy and surface support system of the present invention is designed to provide a one bed solution for acute care including critical care, step down/progressive care, med-surg, high acuity subacute care, PACU, and sections of ED. The modular therapy and support surface system of the present invention provides therapies that benefit a large percentage of the patient population in an acute care hospital.
The bed of the present invention includes an air handling unit located on a bed frame which is capable of supplying air pressure and/or a vacuum to all the therapy and support surface modules. Typically, the air handling unit is mounted on the base frame of the bed. Preferably, the air handling unit drives two lines simultaneously for supplying both air pressure and vacuum to the air therapy modules. A header connector is coupled to the air handling unit by a plurality of air lines. The header connector is configured to couple the air handling unit to a selected modular air therapy device support surface.
The modular therapy and support surface components for the different therapies are contained within the sleep surface on the bed, enabling a caregiver to install, initiate, or remove a desired air therapy from the bed without moving the patient off the original support surface. The modular design of the present invention allows modules for air therapy to have reduced size. Therefore, the modules can be delivered after the bed and stored easily. The air handling unit of the present invention is coupled to therapy control modules that contain air distribution means such as adjustable valves and sensors by a simple connection of pneumatic lines to the control modules.
According to one aspect of the present invention, a bed includes a base frame, a deck coupled to the base frame, an electrical communication network, and an air handling unit mounted on the base frame. The bed also includes a plurality of air therapy devices located on the bed, and a plurality of control modules. Each control module includes a connector for coupling a corresponding air therapy device to the air handling unit and to the electrical communication network. Each control module also includes a controller for operating the corresponding air therapy device with the air handling unit based on command signals received from the electrical communication network.
The bed further includes a control unit coupled to the electrical communication network for transmitting command signals for the plurality of air therapy devices over the electrical communication network to control operation of the plurality of air therapy devices. The control unit includes a display and a user input. Each control module transmits display commands to the display related to the corresponding air therapy device. The display commands from the control modules provide a menu driven list of options to the display to permit selection of control options for the plurality of air therapy devices from the user input.
In the illustrated embodiment, one of the plurality of air therapy devices is a support surface air bladder located on the deck. The support surface air bladder includes a plurality of independently controlled air zones. One of the plurality of control modules is a decubitus prevention control module coupled to the support surface air bladder to control each of the plurality of air zones of the support surface with a common connection to the air handling unit. Another of the plurality of control modules is a decubitus treatment control module for independently coupling the plurality of air zones of the support surface air bladder to the air handling unit.
Another of the plurality of air therapy devices is a pulmonary rotation bladder located between the deck and the support surface air bladder. A pulmonary rotation control module is provided for coupling the pulmonary rotation air bladder to the air handling unit. The pulmonary rotation control module is coupled to the electrical communication network.
Yet another of the plurality of air therapy devices is a sequential compression therapy device. A sequential compression device air control module is provided for coupling the sequential compression device to the air handling unit. The sequential compression device air control module is coupled to the electrical communication network.
Still another of the plurality of air therapy devices is a pulmonary percussion and vibration bladder located on the deck for providing pulmonary percussion and vibration therapy. A pulmonary percussion and vibration control module is provided for coupling the percussion and vibration bladder to the air handling unit. The percussion and vibration module is coupled to the electrical communication network. Alternatively, the percussion and vibration control module is configured to couple a selected air zone of the support surface air bladder to the air handling unit to provide percussion and vibration therapy in the selected air zone.
An auxiliary air port control module is coupled to the air handling unit and to the electrical communication network. The air port control module provides an auxiliary air outlet on the bed.
According to another aspect of the present invention, a control module is provided for activating an air therapy device on a bed which includes a base frame, a deck coupled to the base frame, an electrical communication network, an air handling unit mounted on the base frame, a graphical interactive display coupled to the electrical communication network for transmitting and receiving command signals from the communication network, and a plurality of air therapy devices stored on the bed. The control module includes at least one electrically controlled valve having an input and an output, at least one pressure sensor having an input and an output, and an electronic controller coupled to and controlling the at least one electrically controlled valve and coupled to the output of the at least one pressure sensor. The control module also includes a connector for coupling the input of the valve to the air handling unit on the bed, for coupling the output of the valve to the selected air therapy device, for coupling the input of the pressure sensor to the selected air therapy device, and for coupling the controller to the electrical communication network on the bed so that the controller receives the command signals from the graphical interactive display to control the selected air therapy device.
The graphical interactive display includes a display and a user input. The controller transmits display command signals to the graphical interactive display to display information related to the selected air therapy device on the display. The display commands from the controller provide a menu driven list of control options for the selected air therapy device to the display to prompt selection of various control options for the selected air therapy device from the user input.
If the selected air therapy device includes a plurality of air zones, the control module includes an electrically controlled valve for each of the plurality of air zones to couple the plurality of air zones to the air handling unit on the bed independently. The control module also includes a separate pressure sensor for each of the plurality of air zones.
According to yet another aspect of the present invention, a bed includes a base frame, a deck coupled to the base frame, an electrical communication network, an air handling unit mounted on the base frame, and a header connector including an electrical connector coupled to the electrical communication network and a pneumatic connector coupled to the air handling unit. The bed also includes a plurality of exchangeable air therapy devices. Each of the air therapy devices includes at least one air zone, a therapy control module having a controller, a valve coupled to each air zone of the air therapy device, and a module connector configured to mate with the header connector to couple the valve to the air handling unit and to couple the controller to the electrical communication network so that each of the plurality of exchangeable air therapy devices use the same air handling unit and electrical communication network.
In the illustrated embodiment, the module connector includes a first connector coupled to an input of the valve and a second connector coupled to the controller, the first connector of the module connector being configured to mate with the pneumatic connector of the header connector on the bed to couple the air handling unit to the at least one air zone of the air therapy device through the corresponding valve and the second connector being configured to mate with the electrical connector of the header connector on the bed to couple the electrical communication network to the controller so that the controller receives commands from the electrical communication network to control air flow to the air therapy device through the valve.
According to still another aspect of the present invention, the modular support surface of the present invention includes an improved surface foot section specifically designed for use with a bed having an articulating deck movable from a normal bed position to a chair position. The surface foot section is configured to retract or shorten as the bed moves to the chair position to enable a patient's feet to be placed on the floor or on a foot prop. The foot section also collapses or thins to maintain an acceptable chair seat size which also enables the patient's feet to be placed on the floor or foot prop.
In the illustrated embodiment, a surface foot section apparatus is provided for a bed including a base frame, an articulating deck coupled to the base frame, the articulating deck including a generally planar foot deck section, the articulating deck being movable from a bed configuration to a chair configuration. The surface foot section apparatus includes a first set of air bladders configured to collapse in a first direction generally parallel to the foot deck section when the first set of air bladders is deflated, and a second set of air bladders located adjacent the first set of air bladders. The second set of air bladders is configured to collapse in a second direction normal to the foot deck section when the second set of air bladders is deflated so that the surface foot section has a substantially reduced thickness and a substantially reduced length when the first and second bladders are deflated. The surface foot section apparatus also includes a foot section control module for selectively inflating and deflating the first and second sets of air bladders. The foot section control module deflates the first and second sets of air bladders when the articulating deck is in the chair configuration, and the foot section control module inflates the first and second sets of air bladders when the articulating deck is in the bed configuration.
Preferably, the length of the surface foot section is reduced by at least 40% when the first and second air bladders are deflated and the thickness of the surface foot section is reduced by at least 80% when the first and second air bladders are deflated. This feature maintains an appropriate size for a seat section of the chair and permits a patient's feet to touch the floor when the bed is in the chair configuration. The foot deck section is movable from an extended position to a retracted position to shorten the foot deck section as the articulating deck moves to the chair configuration.
Also in the illustrated embodiment, each of the second air bladders is independently controlled as a separate air zone by the foot section control module. The foot section control module selectively inflates and deflates the second air bladders to provide a heel pressure relief in the surface foot section. The first set of air bladders is commonly controlled as a single air zone by the foot section control module.
According to a further aspect of the present invention, a pulmonary rotation therapy apparatus is provided for use on a bed having a base frame, a deck coupled to the base frame, and a support surface located on the deck. The pulmonary rotation therapy apparatus includes a normally deflated rotation air bladder located between the support surface and the deck. The rotation air bladder remains deflated during normal use of the bed. It is understood that the rotation air bladder can be normally inflated and used as a support surface for the bed, if desired. The pulmonary rotation therapy apparatus also includes a pulmonary rotation control module coupled to the rotation air bladder. The pulmonary rotation control module selectively inflates and deflates portions of the rotation air bladder to provide rotational therapy to a body located on the support surface.
In the illustrated embodiment, the rotation air bladder includes a plurality of elongated air bladders extending generally parallel to a longitudinal axis of the bed. The pulmonary rotation control module selectively inflates or deflates the plurality of air bladders to control rotation of the patient on the support surface. The rotation air bladders are divided into at least three separate air zones which are independently controlled by the pulmonary control module.
Additional objects, features, and advantages of the invention will become apparent to those skilled in the art upon consideration of the following detailed description of the preferred embodiment exemplifying the best mode of carrying out the invention as presently perceived.

BRIEF DESCRIPTION OF THE DRAWINGS
The detailed description particularly refers to the accompanying figures in which:
FIG. 1 is a perspective view of a chair bed in accordance with the present invention in a bed position showing a side rail exploded away from the chair bed, head side rails and foot side rails positioned along longitudinal sides of a deck, and a swinging foot gate in a closed position;
FIG. 2 is a view similar to FIG. 1 showing the chair bed in the sitting or chair position having a head section of an articulating deck moved upwardly to a back-support position, a thigh section of the deck inclined slightly upwardly, a foot section of the deck moved to a generally vertical downwardly extending down position, a foot portion of the mattress being deflated, and swinging gates moved to an open position with one swinging gate folded next to the chair bed;
FIG. 3 is a diagrammatic view of the chair bed of FIG. 1 showing the chair bed in the bed position including a mattress having an upwardly-facing sleeping surface held a predetermined first distance above the floor, the deck being in an initial bed position supporting the sleeping surface in a generally planar configuration, and the foot section being a first length;
FIG. 4 is a diagrammatic view showing the chair bed in a low position;
FIG. 5 is a diagrammatic view showing the chair bed in a Trendelenburg position;
FIG. 6 is a diagrammatic view showing the chair bed in a reverse Trendelenburg position;
FIG. 7 is a diagrammatic view showing the chair bed in an intermediate position having a head end of a head section of the deck pivoted slightly upward from the initial position of the deck, a seat section positioned to lie in the horizontal plane defined by the seat section in the initial position of the deck, and the foot section being inclined slightly so that the foot end of the foot section lies below the position of the foot section when the deck is in the initial position of the deck;
FIG. 8 is a diagrammatic view showing the chair bed in the chair position with the head end of the head section pivoted upwardly away from the seat section to a back-support position, the seat section lying generally horizontal as in the initial deck position, the thigh section being raised upwardly, the foot section extending downwardly from the thigh section and being a second shorter length, and the portion of the mattress over the foot section being deflated;
FIG. 9 is a block diagram illustrating a plurality of electronic control modules of the present invention connected in a peer-to-peer network configuration;
FIG. 10 is a block diagram illustrating the modular therapy and support surface system of the present invention including a plurality of control modules for controlling various air therapy devices and surface sections of a support surface and illustrating an air supply module for controlling an air handling unit and a switching valve to selectively supply air pressure and a vacuum to the various therapy devices and surface sections;
FIG. 11 is a diagrammatical illustration of the configuration of an air therapy control module;
FIG. 12 is an exploded perspective view illustrating a foam surface foundation with side bolsters configured to be positioned on a deck of the bed, an upper foam support surface, and an inflatable and deflatable surface foot section;
FIG. 13 is a perspective view illustrating the surface foot section in an inflated configuration when the bed is in a normal bed position and illustrating the surface foot section in a retracted and collapsed configuration when the bed is in a chair position;
FIG. 14 is a diagrammatical view further illustrating how the surface foot section retracts or shortens and collapses or thins as the bed moves from the bed position to the chair position;
FIG. 15 is a diagrammatical view of the control module and bladder configuration of the surface foot section;
FIG. 16 is a partial perspective view with portions broken away illustrating another embodiment of the surface foot section;
FIG. 17 is an exploded perspective view of another embodiment of the present invention illustrating a pulmonary therapy rotational bladder located between a deck of the bed and the surface foundation and illustrating an upper air bladder support surface located above the surface foundation in place of the upper foam support surface of FIG. 10;
FIG. 18 is a diagrammatical end view illustrating the configuration of the modular therapy and support surface of the present invention when the pulmonary bladders are all deflated;
FIG. 19 is a diagrammatical view similar to FIG. 15 illustrating inflation of left side pulmonary bladders to rotate a patient to the right;
FIG. 20 is a diagrammatical view similar to FIGS. 15 and 16 illustrating inflation of the right side pulmonary bladders to rotate the patient to the left; and
FIG. 21 is a block diagram illustrating another embodiment of the present invention illustrating separate exchangeable surfaces or therapy devices which are each coupled to a control module including pneumatic control valves and sensors, an electrical connection, and a processor for communicating with an air and power handling unit on the bed and with a graphical interface display on the bed through the electrical communication network of the bed.

DETAILED DESCRIPTION OF DRAWINGS
A chair bed 50 in accordance with the present invention having a head end 52, a foot end 54, and sides 56, 58 is illustrated in FIG. 1. As used in this description, the phrase "head end 52" will be used to denote the end of any referred-to object that is positioned to lie nearest head end 52 of chair bed 50. Likewise, the phrase "foot end 54" will be used to denote the end of any referred-to object that is positioned to lie nearest foot end 54 of chair bed 50.
Chair bed 50 includes a base module 60 having a base frame 62 connected to an intermediate frame module 300 as shown in FIG. 1. Casters 70, 72, 74 and 76 support the base frame 62. An articulating deck/weigh frame module 400 is coupled to intermediate frame module 300. Side rail assemblies 800, 802, 804, 806 and an extended frame module 610 having a swinging foot gate 622 are coupled to articulating deck/weigh frame module 400. A mattress 550 is carried by articulating deck/weigh frame module 400 and provides a sleeping surface or support surface 552 configured to receive a person (not shown).
Chair bed 50 is manipulated by a caregiver or by a person (not shown) on sleeping surface 552 using hydraulic system module 100 so that mattress 550, an intermediate frame 302 of intermediate frame module 300, and an articulating deck 402 of articulating deck/weigh frame module 400 assume a variety of positions, several of which are shown diagrammatically in FIGS. 3-8.
Articulating deck 402 includes a head section 404, a seat section 406, a thigh section 408, and a foot section 410. Mattress 550 rests on deck 402 and includes a head portion 558, a seat portion 560, a thigh portion 562, and a foot portion 564, each of which generally corresponds to the like-named portions of deck 402, and each of which is generally associated with the head, seat, thighs, and feet of the person on sleeping surface 552.
Chair bed 50 can assume a bed position having deck 402 configured so that sleeping surface 552 is planar and horizontal, defining an initial position of deck 402 as shown in FIG. 1 and as shown diagrammatically in FIG. 3. In the bed position, sleeping surface 552 is a predetermined first distance 566 above the floor. Chair bed 50 can also be manipulated to assume a low position shown diagrammatically in FIG. 4 having deck 402 in the initial position and having sleeping surface 552 a predetermined second distance 568 above the floor, the second distance 568 being smaller than first distance 566. The foot deck section 410 of the articulating deck 402 includes a pivoting portion 466 and a contracting portion 462. Foot deck section 410 has a first length 465 when the deck 402 is in the initial position.
Chair bed 50 can be moved to a Trendelenburg position shown diagrammatically in FIG. 5 having deck 402 in a planar configuration and tilted so that head end 52 of sleeping surface 552 is positioned to lie closer to the floor than foot end 54 of sleeping surface 552. Chair bed 50 can also achieve a reverse Trendelenburg position shown diagrammatically in FIG. 6 having deck 402 in a planar configuration and tilted so that foot end 54 of sleeping surface 552 is positioned to lie closer to the floor than head end 52 of sleeping surface 552.
As described above, chair bed 50 is convertible to a sitting or chair position shown in FIG. 2 and shown diagrammatically in FIG. 8. In the chair position, head end 52 of head section 404 of deck 402 is pivoted upwardly away from intermediate frame 302 to a back-support position providing a pivotable backrest so that head section 404 and intermediate frame 302 form an angle 512 generally between 55 and 90 degrees. Seat section 406 of deck 402 is positioned to lie generally horizontally as in the initial position, foot end 54 of thigh section 408 is slightly upwardly inclined, and foot section 410 of deck 402 extends generally vertically downwardly from thigh section 408 and has a length 464 that is shorter length 465 than when deck 402 is in the initial position. Foot portion 564 of mattress 550 is inflatable and is in a deflated condition when chair bed 50 is in the chair position. Foot portion 564 of mattress 550 is thinner and shorter when deflated than when inflated.
Chair bed 50 is capable of assuming positions in which head, thigh, and foot sections 404, 408, 410 of deck 402 are in positions intermediate to those shown in FIGS. 3 and 8. For example, chair bed 50 can assume an intermediate position shown diagrammatically in FIG. 7 having head end 52 of head section 404 of deck 402 pivoted slightly upwardly from the initial position, seat section 406 positioned to lie in the same generally horizontal plane as in the initial position, foot end 54 of thigh section 408 raised slightly upwardly from the initial position, and foot section 410 being inclined so that foot end 54 of foot section 410 lies below head end 52 of foot section 410.
The electrical system architecture of the hospital bed of the present invention includes a plurality of electronically controlled modules located on the bed which are interconnected in a peer-to-peer configuration. This peer-to-peer communication network configuration enables any of the plurality of modules to communicate directly with another module in the network without the need for a master controller. In the preferred embodiment, information flow between the electronic modules is primarily accomplished through the use of a twisted pair network channel, although other physical protocols would be acceptable.
Details of the mechanical structure of the bed, the electronic control modules, and the peer-to-peer communication network of the present invention are described in copending U.S. patent application Ser. No. 08/511,711, filed Aug. 4, 1995, , the disclosure of which is hereby expressly incorporated by reference into the present application.
FIG. 9 is a block diagram illustrating the plurality of electronic control modules for controlling operation of the hospital bed. The plurality of modules are coupled to each other using a twisted pair network channel in a peer-to-peer configuration. The peer-to-peer network extends between first and second network terminators 1012 and 1013. Network terminator 1012 is coupled to an air supply module 1014. Air supply module is coupled via the network cable to an accessory port module 1016. Accessory port module 1016 is coupled to the bed articulation control module (BACM) 1018. BACM 1018 is coupled to a communications module 1020. Communications module is coupled to a scale instrument module 1022. Scale instrument module is coupled to a surface instrument control module 1024. Surface instrument control module is coupled to a position sense and junction module 1026. Position sense module 1026 is coupled to the network terminator 1013. A left side standard caregiver interface module 1028 is also coupled to the network by a tee connection in the position sense module 1026. The right side standard caregiver interface module 1030 and a graphic caregiver interface module 1032 are also coupled to the network using the tee connector in the position sense module 1026.
It is understood that the modules can be rearranged into a different position with the peer-to-peer communication network. The modules are configured to communicate with each other over the network cable without the requirement of a master controller. Therefore, modules can be added or removed from the network without the requirement of reprogramming or redesigning a master controller. The network automatically recognizes when a new module is added to the network and automatically enables a control interface such as the graphic caregiver interface module 1032 to display specific module controls for the added module. This eliminates the requirement for separate controls on the individual modules.
Power for the communication network is supplied by a power supply and battery charge module 1062. Power supply 1062 is coupled to a power entry module 1063 which is coupled to an AC main plug 1065. Power supply module 1062 converts the AC input from plug 1065 to DC levels to be used by the electronic modules. The power supply module 1062 also provides power for limited bed functionality upon removal of the AC main power plug 1065 through a battery 1067. The power supply module 1062 contains an automatic battery charging circuit with an output to indicate battery status. The power module 1062 also control a hydraulic pump 1055.
Details of the modular therapy and support surface apparatus of the present invention are illustrated in FIG. 10. The support surface of the present invention is configured to be positioned over a bed deck 402 of a hospital bed. The support surface includes a surface foundation 1500 located on the bed deck. An inflatable and deflatable surface foot section 1502 is located adjacent surface foundation 1500. For certain applications, an upper foam support surface 1504 is located on foundation 1500. Upper foam support 1504 is typically used for short hospital stays. An upper air bladder 1506 can also be positioned over surface foundation 1500. A rotation bladder 1508 is located between the surface foundation and the bed deck. An optional percussion bladder 1510 may be inserted in place of a section of upper air bladder 1506. A sequential compression device 1512 for venous compression therapy of a patient is also provided.
A plurality of separate treatment and surface control modules are provided for interconnecting the various treatment devices and support surface bladders to the communication network of the bed and to on-board air handling unit 1046. Specifically, the present invention includes a foot section control module 1014, a decubitus prevention control module 1516, and a decubitus treatment control module 1518. The modular therapy apparatus further includes a pulmonary rotation control module 1520, a sequential compression device air control module 1522, and a pulmonary percussion and vibration control module 1524. An auxiliary air port control module 1526 is also provided. The air port control module 1526 provides for auxiliary air output for manual filling of auxiliary bladder systems for positioning, safety barriers, clinical treatments such as burn contractures, and other purposes.
Each of the modules is designed to physically and functionally connect the various bladders and treatment devices to both the communication network of the hospital bed through the surface instrument module 1024 and to the air handling unit 1046 which is controlled by air supply module 1014. Air supply module 1014 is coupled to the peer-to-peer communication network. Air supply electronics 1528 are connected to air supply module 1014 for controlling air handling unit 1046 and switching valve 1530 based on network commands for controlling the various surface and treatment modules illustrated in FIG. 10.
Air handling unit 1046 is configured to supply air under pressure to switching valve 1530 on line 1532. Air handling unit 1046 also applies a vacuum to switching valve 1530 through line 1534. An output of switching valve 1530 is coupled to a connector block 1536. Connector block 1536 provides an air and vacuum supply line to each of the surface control and treatment control modules as illustrated in block 1538 of FIG. 10. It is understood that dual control lines for both air and vacuum can be supplied to each of the surface control and treatment control modules of FIG. 10. This dual control allows each module to apply pressure and vacuum simultaneously to different zones of a bladder or treatment device.
The surface instrument module 1024 which is also coupled to the peer-to-peer communication network is electrically coupled to each of the surface control modules and treatment control modules as illustrated in block 1540 of FIG. 10. This network connection permits all the modules to receive input commands from other network modules and to output information to the network.
Details of a therapy or support surface control module 1542 are illustrated in FIG. 11. It is understood that the details of foot section module 1514, prevention module 1516, treatment module 1518, pulmonary rotation module 1520, SCD air module 1522, pulmonary percussion/vibration module 1524, and air port module 1526 include the same or similar structural components as module 1542 illustrated in FIG. 11. The FIG. 11 embodiment illustrates the air handling unit 1046 coupled directly to connector block 1536 by both an air pressure supply line 1544 and a vacuum supply line 1546. As discussed above, lines 1549 and 1546 from air handling unit may be coupled to a switching valve 1530 and only a single pressure/vacuum tube may be coupled to connector block 1536 as illustrated in FIG. 10.
The connector block 1536 is coupled to module connector 1548 located on the hospital bed. Specifically, connector block 1536 is coupled to module connector 1548 by a pressure supply line 1550 and a vacuum supply line 1552. It is understood that a single supply line for both pressure and vacuum could also be used.
Module connector 1548 is also coupled to one of the surface or therapy devices as illustrated by a block 1554 by a pressure supply line 1556, a vacuum supply line 1558, and a sensor supply line 1560. Depending upon the particular surface or therapy device, more than one pressure, vacuum, and sensor lines may be connected between the connector block 1548 and the surface or therapy device 1554. Typically, each separate air zone of the surface or therapy device will have its own pressure, vacuum, and sensor lines. For illustration purposes, however, only a single set of supply lines will be discussed.
The bed also includes an electrical connector 1562 coupled to surface instrument module 1024 of the peer-to-peer communication network of the bed by suitable cable 1564. The therapy or surface control module 1542 illustrated in FIG. 11 is designed to facilitate coupling of the control module 1542 to the bed. Each of the surface and treatment options illustrated in FIG. 10 is provided in the bed with a pneumatic connector such as connector 1548 and an electrical connector such as connector 1562 provided for each of the surface and therapy devices. The module 1542 is easily installed by coupling connector 1548 on the bed to a mating connector 1566 of module 1542. In addition, a mating electrical connector 1568 is provided on module 1542 for coupling to electrical connector 1562 on the hospital bed. The configuration of module 1542 permits a simple "slide in" connection to be used to install the module 1542 and activate the surface of therapy device 1554.
An air pressure input from pneumatic connector 1566 is coupled to an electrically controlled valve 1570 by a supply line 1572. An output of valve 1570 is coupled to a pressure output port 1571 by line 1574. Port 1571 is coupled to the surface or therapy device 1554 by pressure supply line 1556.
The vacuum supply line 1552 from connector block 1536 is coupled to an electrically controlled valve 1576 by line 1578 of control module 1542. An output of valve 1576 is coupled to a vacuum port 1577 of connector 1566 by line 1580. Vacuum port 1577 is coupled to the surface or therapy device 1554 by the vacuum supply line 1558. The electrically controlled valves 1570 and 1576 are controlled by output signals on lines 1582 and 1584, respectively, from a control circuit 1586 of module 1542. Control circuit includes a microprocessor or other controller for selectively opening and closing valves 1570 and 1576 to control surface or treatment device 1554.
It is understood that several valves may be used for each surface or treatment device. For instance, the upper air bladder 1506 may have a plurality of different air zones which are independently controlled. In this instance, separate pressure and vacuum and sensor lines are coupled to each zone of the air bladder. A electrically controlled valve is provided for each pressure and sensor line in each zone to provide independent controls for each zone.
Module 1542 also includes a pressure sensor 1588. Pressure sensor 1588 is coupled to sensor supply line 1560 by line 1590. Pressure sensor 1588 generates an output signal indicative of the pressure in the particular zone of the surface or therapy device 1554. This output signal from pressure sensor 1588 is coupled to the control circuit 1586 by line 1592.
Control circuit 1586 is also coupled to an electrical connector 1568 by a suitable connection 1594 to couple the control circuit 1586 of module 1542 to the surface instrument module 1024. Therefore, control circuit 1586 can receive instructions from the other modules coupled to the peer-to-peer communications network illustrated in FIG. 9. Control circuit 1586 can also output information related to the particular surface or therapy device 1554 to the network. Specifically, the graphical interactive display 1664 or the graphic caregiver interface module 1032 is coupled to the electrical communication network for transmitting command signals for the plurality of air therapy devices over the electrical communication network to control operation of the plurality of air therapy devices. The graphical interactive display includes a display and a user input. Each control module transmits display commands to the display related to the corresponding air therapy device. The display commands from the control modules provide a menu driven list of options to the display to permit selection of control options for the plurality of air therapy devices from the user input.
Details of the structural features of the modular therapy and support surface are illustrated in FIGS. 12-21. FIG. 12 illustrates a deck portion 1596 of a hospital bed. Illustratively, deck portion 1596 is a step deck having a cross-sectional shape best illustrated in FIGS. 18-20. Illustratively, deck 1596 includes a head section 1598, a seat section 1600, and a thigh section 1602. Sections 1598, 1600, and 1602 are all articulatable relative to each other.
The modular therapy and support surface system of the present invention includes surface foundation 1500 including a foundation base 1606 and side bolsters 1608 and 1610. Preferably, side bolsters 1608 and 1610 are coupled to opposite sides of foundation base 1606. Foundation base 1606 includes foldable sections 1612 and 1614 to permit the foundation 1500 to move when the step deck 1596 articulates.
The hospital bed also includes an expanding and retracting foot section 410 to facilitate movement of the hospital bed to the chair position. Surface foot section 1502 is located over the retracting mechanical foot portion 410. Surface foot section 1502 is described in detail below with reference to FIGS. 13-16.
The FIG. 12 embodiment includes an upper foam surface insert 1504 configured to the positioned on the foam foundation base 1606 between side bolsters 1608 and 1610. Foam surface 1504 provides a suitable support surface for a patient who is mobile and whose length of stay is expected to be less than about two days.
The surface foot section 1502 is particularly designed for use with the chair bed of the present invention. The foot section 1502 includes a first set of air bladders 1618 and a second set of air bladders 1620 alternately positioned with air bladders 1618. Air bladders 1618 and 1620 are configured to collapse to a near zero dimension when air is withdrawn from the bladders 1618 and 1620. The first set of bladders 1618 are oriented to collapse in a first direction which is generally parallel to the foot section 410 of the bed deck as illustrated by double headed arrow 1622. The second set of bladders 1620 are configured to collapse in a second direction generally perpendicular to the foot deck section 410 as illustrated by double headed arrow 1624. This orientation of bladders 1618 and 1620 in foot section 1502 causes the foot section 1502 to retract or shorten and to collapses or thin as the bladders 1618 and 1620 are deflated by the foot section control module 1514 as the hospital bed moves from a bed orientation to a chair orientation. In the chair orientation, the foot deck section 410 and surface foot section 1502 move from a generally horizontal position to a generally vertical, downwardly extending position. Preferably, the foot deck section 410 moves from a retracted position to an extended position to shorten the foot deck section as the articulating deck of the bed moves to a chair configuration. Movement of the foot deck section 410 is controlled either by a cylinder coupled to the contracting portion 462 of the foot deck section 410, or by an air bellows controlled by a bellows control module coupled to the air handling unit 1046 and the air supply module 1014.
The minimizing foot section 1504 is further illustrated in FIG. 14. The surface foot section 1502 deflates as it moves from the bed position to the chair position in the direction of arrow 1626. In the bed position, the surface foot section 1502 has a length of about 27 inches (68.6 cm) and a thickness of about 5 inches (12.7 cm) when the bladders 1618 and 1620 are fully inflated. When in the downwardly extended chair position illustrated at location 1628 in FIG. 14, the surface foot section is fully deflated and has a length of about 14 inches (35.6 cm) and a thickness of preferably less than one inch (2.54 cm). The length of the surface foot section is preferably reduced by at least 40% and the thickness of the surface foot section is preferably reduced by at least 80% as the bed moves to the chair configuration. The width of the surface foot section 1502 remains substantially the same in both the bed orientation and the chair orientation.
Pressure control in the surface foot section 1502 is illustrated diagrammatically in FIG. 15. Each of the vertically collapsible bladders 1620 are separately coupled to foot section control module 1514 by pressure/vacuum supply lines 1630 and sensor lines 1632. Therefore, each of the three bladders 1620 are independently coupled to and controlled by foot section control module 1514. Each of the three horizontally collapsing bladders 1618 are commonly connected to a common pressure/vacuum source of the foot section control module as illustrated line 1634. A single sensor line 1636 is used to determine the pressure in the common zone of the interconnected bladders 1618. The control configuration illustrated in FIG. 15 permits independent inflation and deflation of bladders 1620 to provide heel pressure relief in foot section 1502. Details of the heel pressure management apparatus are illustrated in copending U.S. patent application Ser. No. 08/367,829 filed Jan. 3, 1995, now U.S. Pat. No. 5,666,681 owned by the assignee of the present application, the disclosure of which is hereby expressly incorporated by reference into the present applications.
Another embodiment of the foot section 1502 is illustrated in FIG. 16. In this embodiment, bladders 1618 have been replaced by diamond shaped bladders 1640. It is understood that any shape which collapses in a specified direction upon deflation may be used in foot section 1502 of the present invention to provide the shortening or retracting and thinning or collapsing features discussed above.
Additional surface and treatment options of the modular air therapy and support surface apparatus are illustrated in FIG. 17. In FIG. 17, an upper air bladder 1506 is located on foam foundation base 1606 between side bolsters 1608 and 1610. Upper air bladder 1506 includes a plurality of adjacent air tubes or bladders 1642 oriented transverse to a longitudinal axis of the bed. Illustratively, bladders 1642 are connected in three commonly controlled zones 1644, 1646, and 1648. It is understood that more zones may be provided. If desired, each bladder 1642 may be controlled independently.
The surface instrument module 1024 receives commands from the BACM 1018 and the position sense module 1026 to reduce the pressure in a seat section defined by zone 1644 of the upper air bladder 1506 as the bed moves to the chair configuration in order to distribute a patient's weight. A thigh section of the deck is angled upwardly to help maintain the patient in a proper position on the seat when the bed is in the chair configuration.
For the upper surface decubitus prevention, the three supply tubes 1650 of upper air bladder 1506 are all connected to a common pressure source through prevention module 1516. For the upper surface decubitus treatment, the three supply lines 1650 are coupled to three separate valves in treatment module 1518 to control each of the zones 1644, 1646, and 1648 of upper air bladder 1506 independently.
A pulmonary rotation bladder 1508 is located between foundation base 1606 and step deck 1596. It is understood that rotation bladder 1508 may be positioned between foundation base 1606 and upper air bladder 1506 if desired. Rotation bladder 1508 includes separate bladders 1650 which are oriented to run parallel to a longitudinal axis of the hospital bed. Illustratively, three separate pressure zones 1652, 1654, and 1656 are provided in rotation bladder 1508. In the illustrated embodiment, each of the pressure zones 1652, 1654, and 1656 are independently controlled by pressure supply lines 1658. Each pressure supply line is coupled to a separate valve in pulmonary control module 1520 illustrated in FIG. 10. A separate sensor line (not shown) for each zone 1652, 1654, and 1656 is also coupled to pulmonary rotation control module 1520.
Pulmonary rotation bladder 1508 is stored in a deflated position within the bed until it is desired to treat the patient with rotational therapy. In this embodiment, the rotation bladder 1508 does not provide a support surface for the patient. The support surface is provided by either upper foam mattress 1504 or upper air bladder 1506. Therefore, rotation bladder 1508 can be stored flat in the bed during normal operation of the bed as illustrated in FIG. 18. It is understood that in another embodiment of the invention, the rotation bladder 1508 may be normally inflated to provide a support surface for the patient.
When it is desired to provide rotational treatment to the patient, a pulmonary rotation control module 1520 is coupled to the bed. The graphical interactive display 1664 of the bed or the graphic caregiver interface module 1032 automatically recognizes that the pulmonary rotation control module 1520 is attached to the bed. Therefore, controls for the pulmonary rotation therapy device can be actuated from the graphical interactive display 1664 or the graphic caregiver interface 1032.
FIG. 18 illustrates the configuration of rotation bladder 1508 in its deflated position during normal operation of the bed with the upper foam mattress 1504 in place of upper air bladder 1506. In FIG. 18, all three zones 1652, 1654, and 1656 of rotation bladder 1508 are deflated or flat.
FIG. 19 illustrates actuation of the rotation bladder 1508 to rotate a patient situated on foam mattress 1504 to the right. Pulmonary rotation control module 1520 controls airflow to fully inflate zone 1656 to partially inflate zone 1654, and to deflate zone 1652 of rotation bladder 1508. FIG. 20 illustrates actuation of the rotation bladder 1508 to rotate the patient to the left. Pulmonary rotation control module 1520 fully inflates zone 1652, partially inflates zone 1656, and deflates zone 1654 to rotate the patient.
Another embodiment of the modular therapy and support surface invention is illustrated in FIG. 21. In this embodiment, separate exchangeable surfaces are provided. The bed is illustrated by dotted line 1660. As discussed above, the bed includes a peer-to-peer communication network 1662 which is coupled to a graphical interactive display 1664. It is understood that graphical interactive display 1664 may be the graphic caregiver interface module 1032 discussed above. In addition, graphical interface display 1664 may be a display with control switches embedded in a foot board or at another location of the bed to provide a user control for all therapy and surface options. As discussed above, the network 1662 automatically recognizes when a specific therapy module is connected to the bed 1660 and automatically provides control options to the graphical interactive display 1664. The open architecture of the electrical communication network 1662 allows interaction between the added module and the graphical interactive display 1664 without redesigning the system. Bed 1660 includes a surface header connector 1664 coupled to the air handling unit 1046 and to the electrical communication network 1662 by line 1668. In addition, bed 1660 includes therapy header connectors illustrated at block 1670 which are connected to the air and power handling unit 1046 and to the electrical communication network 1662 as illustrated by line 1672.
In this embodiment of the present invention, separate surfaces are provided, including a decubitus treatment surface 1674 and a separate decubitus prevention surface 1676. The decubitus treatment surface 1674 has its own attached control module 1678 for connecting to surface header 1666. Decubitus prevention surface 1676 has its own control module 1680 configured to be coupled to surface header connector 1666. Header connector 1666 is connected to modules 1678 or 1680 in a manner similar to module 1542 in FIG. 11.
Separate therapy modules are also provided. A pulmonary rotation therapy surface 1682 can be added to bed 1660. Rotation therapy surface 1682 is coupled to its own control module 1684 which is configured to be connected to therapy header connector 1670. A sequential compression therapy device 1686 is also provided. Sequential compression device 1686 is coupled to its own control module 1688 which is configured to be connected to therapy header connector 1670. The present invention permits the sequential compression device to use an on board air handling unit 1046 and control system. This eliminates the requirement for a separate air pump and control panel which takes up valuable floor space near the bed and makes the bed difficult to move.
A separate pulmonary percussion and vibration therapy surface 1690 is also provided. Pulmonary percussion and vibration therapy surface is added to bed 1660 in place of a portion of the support surface of the bed. Pulmonary percussion and vibration therapy surface 1690 is coupled to its own control module 1692. Control module 1692 is configured to be coupled to a therapy header connector 1670.
The separate control modules are used to control power and air distribution, and to control user options displayed on the graphical interactive display 1664 for each therapy or surface option. As discussed above in detail with reference to FIG. 11, each control module 1678, 1680, 1684, 1688 and 1692 contain valves, sensors, and electronic control circuits specific to the particular surface or therapy application. All control features are implemented as a menu driven interactive control for the selected therapy or surface module of the present invention on the graphical interface display 1664 or on the graphic care giver interface 1023.
All surface related parameters can be transmitted from surface instrument module 1024 to communications module 1020 and then to a remote location via the hospital network. Surface instrument 1024 can be interrogated by a diagnostic tool coupled to accessory port 1016 if desired. Information related to the surface modules can also be received via modem from a remote location through accessory port 1016.
Although the invention has been described in detail with reference to certain preferred embodiments, variations and modifications exist within the scope and spirit of the present invention as described and defined in the following claims.

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3674019	Grant	Jul 1972
3867732	Morrell	Feb 1975
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4394784	Swenson et al.	Jul 1983
4435864	Callaway	Mar 1984
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5666681	Meyer et al.	Sep 1997

Support surfaces for a bed

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Abstract

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US Referenced Citations (42)

Non-Patent Literature Citations (4)

Divisions (1)

Entry
"The Pillow-Pump.RTM. Alternating Pressure System," Gaymar Industries, Inc. advertising brochures, 8 pages, date unknown.
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"Using Sof .cndot.Care.RTM.just got easier . . . ", Gaymar Industries, Inc. advertising literature, 1 page, 1992.