DE3716263C2 - - Google Patents

Description

The invention relates to an anti-decubitus pad according to the preamble of claim 1.

In such a case as an electrically heated air cushion bed trained document according to DE-OS 24 04 699 the cavity covers the entire bed cover and has as a heating element via an electric heating element. As an air filling is provided for the heatable medium. There the air expands with increasing temperature, results with increasing temperature in the bed cover a higher internal pressure. With regard to the low Volume change of gases when heated by 1 degree Celsius in practice, however, there are only a few Achieve pressure changes. An effective anti-decubitus pad To create pressure changes to reach in the range of a few 100 mm Hg, which only changes in temperature with the known pad in the range of approx. 100 degrees Celsius can be realized. The required temperature changes are even with good thermal insulation associated with dangers to the patient.

Anti-decubitus pads in the form of alternating pressure Pillows with air cells made of a flexible film material are described in DE-PS 21 03 499. To Generation of the alternating pressure it is necessary to fill individual air cells with the help of a pump. However, the noise development of air is common pump felt to be unreasonable because of the use of Compressors or pumps by their operation always  disturbing noises arise. Even when connecting Anti-decubitus pads on existing compressed air conclusions result in adverse noise pollution. Another disadvantage arises from the fact that Compressed air connections are often not available.

From CH-PS 1 63 703 a substance is known which at develops a foam when heated to body temperature, whereby the substance evolves decomposes and experiences an increase in volume. These however, the chemical reaction described is not reversible. When the temperature is lowered namely no regression of the foam and the developed Gas to the source material and thus no reduction in volume.

The invention is based on this prior art based on the task of an anti-decubitus pad to create effective against pressure ulcers is, with large pressure changes without disturbing the Well-being of the patient are possible.

This object is achieved by the characterizing Features of claim 1 solved.

The fact that the swell in the anti-decubitus pad provided cells used medium does not need to be supplied externally all supply lines and with the use of Problems related to pumps or compressors. It is only an electrical power supply is required, which deal with relatively thin and flexible Lines can be realized. When you turn on the electrical current becomes the initially liquid medium heated up and a little above body temperature evaporates. As a result of the phase change  Volume increase results in effective pressure control.

Because the total cavity of the anti-decubitus pad is divided into several cells, the result is Possibility of alternately applying the Cells with pressure a patient's bedsores in particular to avoid effectively. Because it has shown that it is more effective in avoiding Decubitus to vary the support areas in time, instead of applying pressure by distributing body weight to keep a very large area very low, like this e.g. B. happens in the waterbed.

If the individual cells can be controlled individually Containing heating or cooling elements, it is simple Way possible, constantly successive pressure changes to generate so that the patient alternately is supported by the individual cells. By the The cavity is divided into individual cells thus medical treatment, the basic one is different from that in which the body of the Patient lies on the entire surface.

The division of the cavity into cells results in furthermore as an advantage that the necessary Heat transport in the individual cells is less than this for a much larger coherent Cavity would be the case. With regard to the lesser Comparison of the mass of the medium within a cell to the entire cavity is thus the same A faster supply of energy per heating element Temperature rise and thus a faster pressure change.  

Of particular importance is that according to the invention not the volume expansion of a medium depending is exploited by the temperature, but the Transition of a medium between a liquid and a gaseous phase state. As is well known none during a change in a phase state Temperature change as long as both phases are present. In this respect, the invention allows for pressure differences minimal temperature differences.

The medium is preferably 1,2-dibromotetrafluoroethane, that at a little above body temperature People lying temperature evaporates. It is non-toxic non-flammable, non-explosive and non-corrosive.

It is also possible to use a medium that is below the body temperature evaporates when the heating element is replaced by a cooling element. The one for vaping required heat is then from the body of the Delivered to patients. With the help of the cooling elements a pressure drop in a number of selected cells effected at different times.

Appropriate refinements and developments of Invention are characterized in the subclaims.  

The following are exemplary embodiments of the invention explained in more detail with reference to the drawing. It shows

Fig. 1 is a plan view of an assembled from separable cells Antidecubitus support according to the invention,

Fig. 2 is a side view of a second embodiment of the anti-decubitus support according to the invention,

Fig. 3 is a plan view of an anti-decubitus pad with a plurality of cells and permanently connected

Fig. 4 is a plan view of a double-walled cell of an anti-decubitus pad according to the invention.

The anti-decubitus pad shown in Fig. 1 consists of several cells 1, 2, 3, 4, 5, 6 and 7 , which form media-filled, separate chambers or pillows and by means of push buttons 8 or cords along their edges are releasably connected. In this way, an anti-decubitus pad with different dimensions can be buttoned together.

While cells 1 , 3 , 4 , 5 and 7 have a high internal pressure and, as illustrated in FIG. 1, are bulging, the internal pressure in cells 2 and 6 is low. By alternately applying pressure to cells 1 to 7, bedsores of the patient are avoided.

Cells 1 to 7 , like cells 15 to 18 , 20 to 32, consist of a flexible, stretchable material that is non-slip and disinfectable on the outside. The material can be provided on the inside and / or outside with one or more coatings, for example made of plastic and / or metal, in order to ensure tightness and resistance to the filling medium. In Fig. 1, the film 9, the cell 7 is cut open and forming one recognizes an existing within the cell 7 electric heating element 10.

The electric heating element 10 serves to transfer a liquid filled into the cell 7 from the liquid phase to the gaseous phase. This results in a large increase in volume, which is used to inflate the cell 7 . The liquid, of which a residual liquid pool 11 can be seen in FIG. 1, is 1,2-dibromotetrafluoroethane, which has an evaporation temperature which is somewhat above the body temperature of humans. It is particularly advantageous that this liquid is harmless to living beings, non-flammable, non-explosive and neither toxic nor corrosive. The material of the film 9 is chosen so that it is not attacked by either the liquid or the evaporated liquid.

The electrical heating element 10 is designed as a heating tape or heating plate and corresponds to the commercially available heating tapes and heating plates, such as those used for gutter heating or in chemistry. The heating elements 10 of cells 1 to 7 each lie loosely within cells 1 to 7 . It is also possible to connect them to the foils 9 of cells 1 to 7 by vulcanizing, pouring or gluing.

The leads to the individual heating elements of the complete anti-decubitus pad shown in Fig. 1, which consists of cells 1 to 7 , can be fed between or under cells 1 to 7 loose or with fastening elements, for example. Likewise, the feed lines can be glued or glued or cast or vulcanized in, for example. It is also possible to connect the leads to the individual cells 1 to 7 using multiple plugs and sockets from cell to cell. In Fig. 1 you can see a connector 12 to a connecting cable 13 which allows a multi-pin connection of the anti-decubitus pad shown in Fig. 1 with a power supply unit, not shown in the drawing. The various pins 14 of the connector 12 are connected to different outputs of the power supply unit, in which there is a control circuit that allows the heating elements 10 to be supplied individually with current, so that the Heizele elements 10 either individually or in groups be powered to pressurize selected cells 1 through 7 . A time-controlled switchover between the individual heating elements 10 causes a change in the contact surface of the anti-decubitus layer without the need for compressed air or liquids to be filled in or discharged from the outside, which would be associated with noise.

In FIG. 2, a further embodiment of an anti-decubitus support is shown in an end view, partly in section. Between the cells 15 , 16 , 17 and 18 there are support walls 19 which are so thick that they can withstand the pressure of a patient's overlying body. The body facing surface of the support walls are designed so that the broadest possible rounded contact surfaces arise when the cells 15 to 18 no longer contain steam under high pressure, which is shown in Fig. 2 for the cells 16 and 18 , while in Fig. 2, the cells 15 and 17 contain instead of unvaporized liquid is substantially vaporized liquid and therefore are inflated.

The anti-decubitus pad shown in Fig. 2 can be designed so that all cells 15 to 18 are heated up simultaneously and switched off again after a predetermined time. In this way, the body is first lifted from the support walls 19 , where it rests on the flexible curved chamber wall, and then lowered onto the support walls 19 , each ver different body parts are loaded.

It is also possible to heat the cells 15 to 18 in groups, similar to the control described in connection with FIG. 1. In the simplest case, only two groups of heating elements can be formed. Such an embodiment is shown in FIG. 2, in which cells 15 and 17 belong to the first and cells 16 and 18 to the second group. Power is supplied via the connecting cable 13 and the connector 12 with a plurality of connector pins 14 .

The anti-decubitus pad shown in Fig. 3 consists of a plurality of cells 20 to 31 , some of which have a high internal pressure in the manner shown and others a low internal pressure. In contrast to the exemplary embodiment shown in FIG. 1, the cells 20 to 31 are not releasably connected to one another, so that a uniformly manageable anti-decubitus pad is formed. The structure and the control of the individual cells 20 to 31 is designed according to FIG. 1. The Stromver supply of the anti-decubitus pad shown in Fig. 3 takes place via the connecting cable 13 and the connector 12 with its connector pins 14th

It is also possible for the individual cells 1 to 7 or 15 to 18 or 20 to 31 to be multi-walled. Such an exemplary embodiment is shown in FIG. 4 for a single-cell anti-decubitus pad. The cell 32 is double-walled and consists of an outer shell 33 and an inner shell 34 . In the embodiment shown in FIG. 4, the heating element 10 is located within the inner shell 34 . The dots within the inner shell 34 show in FIG. 4 that the filling medium is in the gaseous state and thereby generates a high internal pressure inside the cell 32 .

The cell 32 shown in FIG. 4 can be detachably or non-releasably connected to other cells in accordance with FIG. 1 in order to provide anti-decubitus pads of the desired shape. If the filling medium is 1,2-dibromotetrafluoroethane, it is possible in a simple manner to generate a large volume difference and a locally changing pressure under the person lying on by switching on the heating elements 10 .

If, instead of a medium boiling slightly above body temperature, a medium is used which evaporates somewhat below body temperature, it is possible to use the body heat of the patient lying on the bed to create a phase transition. Instead of the heating elements 10 mentioned in connection with the exemplary embodiments discussed above, cooling elements are then used in order to achieve condensation of the evaporated liquid. Such a cooling element consists, for example, of a vulcanized-in hose through which cold water flows, which is not shown in the drawing.

The inner shell 34 shown in FIG. 4 need not be made of the same material as the outer shell 33 . The outer shell 33 is made of a stretchable material and can be provided on the inside and / or outside with one or more coatings, such as plastic and / or metal coatings. The inner shell 34 can be made of a stretchable material, for example a rubber compound. However, it is also possible to use an inextensible but flexible material, for example a metal or plastic film, instead of a material made from a rubber mixture. This outer shell can also be coated with a non-slip coating. The inner shell 34 can also be coated, wherein a plastic coating, a metal coating or a combined coating of plastic and metal is provided.

With a double-walled anti-decubitus pad accordingly FIG. 4, the heating element 10 can lie loosely inside half of the inner shell 34 or loosely under the outer shell 33 or can be vulcanized or cast or glued inside or outside or between the inner shell 34 and outer shell 33 .

In a known manner, the anti-decubitus pad shown in the execution examples according to FIGS . 1 to 4 can also be provided with an insulating blanket so that the body lying on it is not additionally heated from the pad, unless this heating is desired.

The anti-decubitus pad described can be use especially for people. Areas of application are both in the home care area and in hospital therapy, in the case of long-lasting opera and in elderly care. Similar areas of application are also conceivable in animals. The described anti bedsore can also be used as a car seat cover or the like. The size of the pad is adapted to the respective application.

Claims (12)

1. anti-decubitus pad with a cavity made of a flexible film material, which contains a heatable medium and a heating element, the cavity being inflated to a greater or lesser extent according to the prevailing temperature by the resulting variable pressure, characterized in that the cavity is made up of several cells ( 1 to 7, 15 to 18, 20 to 32 ), each containing a medium that transitions from liquid to gaseous phase state near the patient's body temperature, and that individually controls each cell's phase transition controllable element ( 10 ) for supplying or removing heat is arranged. 2. anti-decubitus pad according to claim 1, characterized in that the medium is 1,2-dibromotetrafluoroethane and for heating the cells ( 1 to 7 , 15 to 18 , 20 to 32 ) electric heating elements ( 10 ) are provided. 3. anti-decubitus pad according to claim 1, characterized characterized that the medium a little liquid boiling below body temperature and the cell is heated by the Body of the patient lying on the bed. 4. anti-decubitus pad according to claim 3, characterized in that the cells ( 1 to 7 , 15 to 18 , 20 to 32 ) are provided with a cooling element. 5. anti-decubitus pad according to claim 4, there characterized in that as cooling ment a hose through which cold water flows is provided. 6. anti-decubitus pad according to claim 2 and 5, characterized in that the hose or the electrical heating element ( 10 ) is vulcanized into the cell wall. 7. anti-decubitus pad according to claim 2 and 6, characterized in that the heating or cooling element is plate-like. 8. anti-decubitus pad according to claim 2 and 6, characterized in that the heating or cooling element is loose in the medium. 9. anti-decubitus pad according to claim 1 or 2, characterized in that the cells ( 1 to 7 , 15 to 18 , 20 to 32 ) assigned heating elements ( 10 ) can be acted upon separately with electrical current. 10. anti-decubitus pad according to claim 9, characterized in that the heating elements ( 10 ) in the various cells ( 1 to 7 , 15 to 18 , 20 to 32 ) can be switched on alternately via a control circuit. 11. Anti-decubitus pad according to one of the preceding claims, characterized in that between the cells ( 15 , 16 , 17 , 18 ) support walls ( 19 ) are provided, through which the patient's body is supported abge at low internal cell pressure. 12. anti-decubitus pad according to one of the preceding claims, characterized in that the cells ( 32 ) are double-walled.