A bioelectrode comprising a skin-side, electrically conducting adhesive layer and a flexible electrical connecting cable which in an electrically insulating cable sheath includes at least one electrical conductor, preferably in the form of a braid comprising a plurality of individual wires or conducting individual fibers.
Bioelectrodes are used in many ways. Either current is fed to the human or animal body as in the case of a defibrillation electrode or stimulation electrode or current is carried off from the body (for example neutral electrodes or measurement electrodes).
The object of the invention is to provide a bioelectrode in which the electrical connecting cable has a good mechanical hold in the electrode and also good electrical contact is ensured in relation to those layers of the electrode, which finally feed the current to the skin or take it therefrom.
According to the invention the object is achieved in that the electrode-side end of the connecting cable is arranged between two thermoplastic layers which are welded together at least region-wise, wherein both thermoplastic layers are electrically conducting and are electrically connected to the electrical conductor of the connecting cable.
The fact of bonding the electrode-side connecting end between two thermoplastic layers, in accordance with the invention, makes it possible on the one hand to achieve a good mechanical hold and at the same time to provide an excellent electrical connection to the two thermoplastic layers which are electrically conducting.
The electrically conducting thermoplastic layers make it possible for the current which is supplied by way of the electrical connecting cable to be uniformly distributed over a larger area or taken off from a larger area. It is however also possible for a specific resistance profile to be incorporated in the electrically conducting thermoplastic layer which can also comprise a plurality of sublayers, for example in such a way that the surface resistance decreases or increases as desired from the central connecting point of the electrode-side cable end to the edge of the electrically conducting thermoplastic layer. At any event a specifically targeted current distribution in relation to an area is possible.
The two thermoplastic layers can be welded together with the inclusion of (by including) the electrode-side connecting cable between the two layers for example thermally or by means of ultrasound.
Further advantages and details of the invention are set forth more fully with reference to the specific description hereinafter.
a shows a first embodiment by way of example of the invention as a diagrammatic exploded view,
a shows a second embodiment by way of example of the invention as a diagrammatic exploded view and
a shows a third embodiment by way of example of the invention as a diagrammatic exploded view and
a shows a fourth embodiment by way of example of the invention as a diagrammatic exploded view and
a shows a fifth embodiment by way of example of the invention as a diagrammatic exploded view and
a shows a sixth embodiment by way of example of the invention as a diagrammatic exploded view and
a and 1b show a first embodiment by way of example of an electrode according to the invention, in particular a defibrillation electrode.
The electrode in
Now in accordance with the invention the electrode-side free end 4a of the connecting cable 4 is arranged between the two thermoplastic layers 2, 3 which are welded together at least region-wise. It is pointed out that the cross-sectional view in
As shown in cross-section in
Materials which can be used for the insulating cable sheath are polyethylene, polypropylene or polyvinyl chloride or the like. The conducting wires can be carbon fiber strands which can comprise several 1000 to several 10,000 individual fibers which can be metallised. Metal braids alone or metal braids combined with carbon fibers can also be used as conducting wires. Such a cable configuration makes it possible for the cable end to be stripped of insulation for example over a length of between 0.5 cm and 2 cm and for the individual wires of the braid then to be fanned open, as diagrammatically shown in
With a layer thickness of the order of magnitude of between 50 and 150 micrometers in respect of the thermoplastic layers 2, 3, that welding operation can be effected at a temperature of between 150° C. and 200° C., with the application of a pressure of between about 1 N/cm2 and 5 N/cm2, wherein the welding duration is desirably between 5 sec and 20 sec.
Alternatively it is also possible to use an ultrasound welding method. Here an operating frequency of the order of magnitude of for example 20 KHz is suitable. The energy input is desirably between 200 Ws and 600 Ws. The pressing pressure is desirably of the order of magnitude of between 50 N/cm2 and 100 N/cm2. The welding times when using ultrasound welding are really short and are desirably less than a second.
In the embodiment shown in
At the skin side the bioelectrode shown in
A metal layer or a metal/metal chloride layer can be arranged between the skin-side conductive adhesive layer 7 and the electrically conducting thermoplastic layer 3, the metal preferably being silver. That layer is denoted by reference 8.
Arranged beneath the conductive adhesive layer 7 is a cover material 9 which can be pulled off and which protects the conductive adhesive layer upon transport and in storage and which is pulled off prior to use. That cover material can comprise plastic materials such as polyethylene terephthalate, polystyrene, polypropylene or the like, which can also be siliconised.
The second embodiment shown in
In the third embodiment of
In the embodiment of
The conducting metal layer is preferably a lacquer. It is preferably mixed at least with metal pigments. In addition it is possible to incorporate metal salts which with their respective metals form a constant self-potential, for example: Ag/AgCl. The metal layer can also be applied by vapor deposition.
In the fifth embodiment of
It is also possible to use a film composite as the layer 10 (for example: metal/polyethylene terephthalate/sealing lacquer), wherein the insulating side is oriented at the skin side. In that case, by virtue of choosing a specific geometry for the layer 10 (for example: star-shape), the current can be optimally distributed from the layer 10, by way of the thermoplastic layer 2 to the thermoplastic layer 3, and the further electrically conducting layers, to the skin.
The sixth embodiment of
It will be appreciated that the invention is not limited to the illustrated embodiments. For example the invention is suitable not only for defibrillation electrodes and electrodes which feed current to the skin (for example: stimulation electrodes) but basically also for electrodes which take current from the skin (for example neutral electrodes, measurement electrodes). The layer structure and the size relationships can differ from the illustrated embodiments. What is essential is that the electrode-side end of the connecting cable is arranged between two layers which are thermoplastically welded together so as to ensure a good mechanical hold and a good electrical connection.
Number | Date | Country | Kind |
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A 1934/2008 | Dec 2008 | AT | national |