1. Field of the Invention
The present invention relates to fluid based support systems and, more particularly, to a pressurized bed for the support of hospitalized patients.
2. General Background and State of the Art
The concept of a patient floating on an air cushion has been implemented by many organizations providing complex and sophisticated beds. Some have used inflatable cushions and other approaches have used plastic beads which are supported by a pressurized air flow. Yet, all such beds are unable to provide adequate support to the patient that significantly reduces the chances of discomfort and bed sores.
All such beds have problems with maintaining a sanitary environment, especially with incontinent patients. Incontinence leads to soiling of the bed and prior to this invention, soiled beds may leave patients lying in unsanitary conditions there is no way to effectively allow the waste to drain away from the patient. Cleaning of such beds is also ineffective as residual waste remains within the bed's crevices and materials. Such residual waste comes into contact when the bed is given to another patient whereby there is a chance of passing along potentially communicable diseases to the next patient.
Other problems have involved mechanical failures for beds with a unitary control system. If the bed's control system fails, the entire bed is not useable. In some other beds, there is only one type of support system. If the support system fails, there is no back-up support system which leaves the patient in discomfort for a period of time.
The above described features and advantages of embodiments of the present invention will be more fully appreciated with reference to the accompanying Figures.
According to the present invention, a plurality of telescoping tubes is supported by air pressure. Much as a “bed of nails” can support the human body without injury, with a sufficient number of tubes, the weight that each tube bears is light enough so that a moderate air pressure in each tube will be adequate. Support springs are provided at the base of each tube to support the body weight should the air supply fail or be turned off.
Each tube can be supplied with air exit apertures near the top for the circulation of air about the resting body. In alternative embodiments, the apertures can be on the body of the tube or in the top of the tube. At the base of each tube is an internal gasket to prevent air loss at the base and to redirect incoming air to elevate the tube and exit near the top. At the top of each tube, a collar is provided to support a bed sheet which has been apertured to fit around the tubes.
A plurality of air supply tubes is mounted to a plenum unit which is connected to an air supply through a quick release valve. A bed may have several plenum units and the plenum units can be arranged in an array of rows, each individually actuable so that different areas of the bed can have different levels of support for a body.
The several plenum units are mounted in a frame with a resilient collar so that limited vertical motion is possible. In conjunction with the plenum units, a roller bar can be moved under the plenum units to sequentially elevate them slightly to provide a rippling motion to the person being supported in the bed. The massaging roller bar can be programmed to provide different combinations of movement to stimulate the person in the bed.
The present invention also provides for an easy and effective means of sanitizing the hospital bed components. Portions or the entire system can be placed in a series of tubs. The first tub functions to soak the soiled bed components in sanitizing liquid for both the break down of soiled debris and disinfection of microbial residue. The second tub functions to rinse off the debris and cleaning liquid. The final tub functions to dry the cleaned bed components and further sanitize the bed components under ultraviolet (UV) radiation. The tubs are configured to have clear observation panels for easy evaluation of the cleaning process.
The above invention also saves on costs. Previous hospital bed models that are soiled or damaged usually have to be destroyed resulting in added cost to buy new beds. The above invention has replaceable segments. And such segments may be individually sanitized in a manner that allows them to be reused. Thus, the life cycle of the present invention and the ease in repair or replacement allows for a much more cost effective alternative. Furthermore, the pressure controls are far more precise and can provide or limit air pressure to the patient, thereby reducing health care costs associated with bed sores and related injuries.
The novel features which are characteristic of the invention, both as to structure and method of operation thereof, together with further objects and advantages thereof, will be understood from the following description, considered in connection with the accompanying drawings, in which the preferred embodiment of the invention is illustrated by way of example. It is to be expressly understood, however, that the drawings are for the purpose of illustration and description only, and they are not intended as a definition of the limits of the invention.
Turning first to
Each support tube 12 may have an outer tube 18 and an inner tube 20. The support tubes 12 have relatively closed ends facing the top surface of the bed, and the ends of the support tubes 12 may have a variety of shapes for example, dome shaped to planar. The support tubes 12 may be of any materials that are capable of providing comfortable support to a patient and at least some component of support tubes 12 are moveable upon application of air pressure. Such materials may range from metals and metal alloy components (e.g. silver), plastics, foams, and foams with laminate coverings. It is preferred that the materials for said support tubes 12 are have antibiotic properties and are sanitizable and sustainable materials.
The inner tube 20 has at least one orifice 22 at the top which allows passage of air 126 through the inner tube 20 and into the outer tube 18. Air 126 from an air pressure source 104 is pumped through the quick release-valve 28, and into plenum chamber 14, which the air 126 enters the inner tube 20, and the outer tube 18. When air 126 enters outer tube 18, the outer tube may be raised upwardly such that it may provide support to the patient lying on the plurality of rows of supporting tubes 12. For better “piston-like” operation of the outer tube 18 moving over the inner tube 20, the inner tube 20 may have one or more external fins 24. The external fins 24 may act as a guide, and may act to provide some friction between interior surface of the outer tube 18 and the exterior surface of the inner tube 20. The outer tube 18 may have an inner collar 26 located at the bottom end of the tube. The inner collar 26 may be used to prevent the outer tube 18 from rising beyond the external fin 24 where the inner collar 26 would abut up against the bottom portion of the external fin 24 which is also shown in
In
Each plenum chambers 14 may be held in place by a yoke mechanism 36 as shown in
Attached to the bottom surface of the clamp 40 is the upper spring 45. When the clamp 40a is released, the clamp 40a may be lifted up and rotated away from the plenum chamber 14 to position 40b so that the movement of the clamp 40b permits the plenum chamber 14 to be lifted out of the yoke mechanism 36. The clamp 40a may be attached to a hinge 56 which has a shaft 58 positioned within the framing wall 38b, and the hinge 56 may allow the clamp 40a to be rotated to the position of the clamp 40b. Upon rotation of the clamp 40b, the shaft 58 may be raised. (not shown)
In releasing the plenum chamber 14, the plenum chamber 14 may slide away and out from the quick the release valve 28. The yoke mechanism 36 further has a base 46 wherein said base 46 has a connected lower spring 48. The lower spring 48 and the upper spring 44 allow the plenum chamber 14 to have a limited vertical movement contact with a massaging roller bar 50 when the plenum chamber 14 is locked into place. The plenum chamber 14 may have an outer structure 52 that has rounded edges 54. The rounded edges 54 allows the roller bar 50 to roll under the plenum chamber 54 wherein the roller bar 50 initially makes partial contact to a lower area of the outer structure 52 of plenum chamber 14 and then causes the plenum chamber 14 to be displaced vertically upward as the roller bar 50 moves underneath the plenum chamber 14.
The top of the bed 10 may have a laminate or fitted sheet 60 with a plurality of apertures 62 where the apertures 62 would fit around each support tube 12 as shown in
The sheet 60 may be a multiple layer sheet 74 which may comprise of a top cotton or linen sheet layer 66, a lower absorption membrane 68 which may be of materials known to those with ordinary skill in the art, and a lower fluid barrier 70 which may be of materials that are water resistant. Between the absorption membrane 68 and the fluid barrier 70, there may be a moisture and temperature sensing film 72. Such film 72 may be of capacitive material that may be connected to sensors that detect humidity and temperature levels, and communicate that information to a computer, which then alerts the caretakers of such conditions. (Not shown).
The multiple layer sheet 74 may be used in all areas of the bed, or it may be used in select locations 76 as shown in
Some areas may have less pressure than other areas that are pressure reduction zones 80, as shown in
Certain regions on the patient 100 may be areas that should not receive any pressure. To allow for selective application of pressure, the bed 10 may be configured with sensing receivers that are located below the laminate sheet 60 that detects certain materials such as but are not limited to, luminescent material. (Not shown) The material may be mixed in with non-toxic paint wherein one may paint the regions on the sheet 60 or patient. The sensing receivers may then send signals to a CPU and communicates to the CPU the location in which pressure on the bed should not be applied. The CPU then regulates the air flow to each plenum chamber 14 segments. (Not shown) The CPU then signals the solenoids for each plenum chamber 14 segments to be active and inactive, and the inactive regions would correspond to the location of the painted area. Painting the regions on the body of the patient 100 allows for better responsiveness as the location of the inactive plenum chambers moves with the patient 100.
As shown in the exemplary embodiment in
The stimulation by the support tubes or the roller bar may be used to provide alternating stimulation. As mentioned above, the roller bar may provide varying stimulation if the servo motor 90 is allowed to continually move the roller bar 50 up and down the bed in various ways. Further, some beds may be configured with multiple rows of support tubes thereby increasing stimulation in some areas that others. Air pressure may also be adjusted in some plenum chambers 14 as shown in
One or more rows of support tubes 12 may be removed from the bed and placed into a sanitizing system as shown in figures
The rows of support tubes 12 along with other components may then be placed into an enclosed rinsing tub 120 as shown in
Each of the above tubs may have transparent lids, which allows the operator to evaluate whether the support tubes and attached bed components have been properly sanitized and cleaned.
A system and apparatus for providing a hospital bed to reduce bed sores and injuries along with a coupled sanitization system has been disclosed. Although the present invention has been described in terms of a preferred embodiment, it will be appreciated that various modifications and alterations might be made by those skilled in the art without departing from the spirit and scope of the invention. Therefore, the invention should be measured only in terms of the claims which follow.
This application claims the benefit of U.S. Provisional Application No. 61/861,816 filed on August 2, 2013.