DE8704334U1 - Sensor for mechanical forces emanating from animal or human bodies - Google Patents

Description

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The invention relates to a sensor according to the preamble of claim 1.

DE-OS 35 12 095 describes a method that makes it possible to monitor, determine and record body functions that have a mechanical effect. These measures can be carried out on humans and animals.

-J _5. They can be used in particular for measuring purposes or for monitoring purposes, for example in intensive care units. An elastic, piezoelectric foil is used to convert the mechanical forces into electrical signals. This foil is placed between the body and a substrate. The voltages generated in this foil are taken from it and fed to a processing circuit, in particular a visual display and/or an acoustic alarm system and/or a digital processing circuit.

To carry out the method, at least one piezoelectric foil with at least one substrate layer is used, whereby the foil can be placed on this. The body to be monitored can be placed on the foil and the substrate arranged underneath. The foil with the substrate can be attached to the body.

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biPacht and, if necessary, pressed against it.

The invention is based on the task of further increasing the security of the monitoring function when carrying out this method.

This problem is solved by the technical teaching of protection claim 1.

To ensure that no geometric electrical compensation can occur in the event of the body being in the most unfavorable position relative to the foil, which would lead to false alarms, the foil is divided into two strip-shaped sections and the strip-shaped sections are alternately connected to one of two separate signal outputs. The advantage is that the sum of the areas of the alternating strip-shaped sections can be equal to one another.

In one embodiment, an electrical coating of the foil is divided into two parts by an insulation such that the body touches one of the divided areas on both sides of the insulation dividing line.

A particularly advantageous embodiment is created by the fact that the foil is coated homogeneously on one side with electrical conductivity and that the other side has an electrically conductive coating which is divided into two comb-shaped layers by a meandering insulation.

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nicely interlocking, electrically separated |

insulated coating surfaces. Each |

this coating surface is provided with its own |

Signal line connected. Signals can be fed separately ( to the processing devices, in particular a logic circuit. The

The comb-like shape of the insulation |, interlocking of the coating surfaces represents

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i The meander-shaped insulation is advantageously produced in such a way that the coating material at the point where insulation is to be provided is removed by etching or mechanical removal. :

The piezoelectric foil is placed between two plastic plates and in a shield. This has the particular advantage that the sensor's own movements, in particular the subsequent movements of the piezoelectric foil, are eliminated. The shield prevents interference caused by electric fields.

Shock waves in the surrounding air, which are generated, for example, by doors or windows slamming, can lead to incorrect evaluations. To compensate for these, in the embodiment described above, at least one edge section of the piezoelectric element is

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A second piezoelectric foil, the polarity (orientation of the molecular dipoles) of which is opposite to that of the first foil, is arranged on the first electric foil. The 5 surface of the second piezoelectric foil is equal to the surface of the first piezoelectric foil, which is acted upon by the animal or human body.

1Q A particularly advantageous embodiment, which also excludes an incorrect evaluation that can be caused by shock waves in the surrounding air, is achieved in that the piezoelectric polarization of alternating, strip-shaped sections in each group of the sections connected to one of the signal outputs is opposite. Surprisingly, it has been shown that in this embodiment it is no longer necessary to provide a second compensation film. In one embodiment of the sensor according to the invention, such a film can be cut into strips and alternating strips of a group can be turned over in such a way that piezoelectric polarizations of the opposite type described are obtained.

However, the electrically conductive coating on each side of the foil can advantageously be divided into strip-shaped, electrically separated sections. Each signal output line can be alternately connected to the electrically conductive coating section on one and the other surface of the foil. When using ^modern* vapor deposition or printing

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techniques, the signal output lines can be meander-shaped through-holes. A particularly well-functioning sensor that is safe from interference is created by placing the piezoelectric foil between two plastic plates and enclosing this assembly in an electrical shield (Faraday).

IQ /Exemplary embodiments of the invention will be explained with reference to the figures in the drawing.

Show it:

Fig. 1 is a schematic plan view of a sensor, Fig. 2 is a sectional view of a sensor,

Fig. 3 is a schematic plan view of another embodiment of a sensor,

Fig. A is an enlarged, perspective partial view of a foil

and

Fig. R is a sectional view of another embodiment of a sensor.

Fig. 1 shows a top view of a piezoelectric foil 1 * The underside of the piezoelectric foil (not shown)

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The electrical film 1 is coated in a homogeneous, electrically conductive manner in a manner known per se. The top side of the piezoelectric film 1 shown has an electrically conductive coating 2. This electrically conductive coating 2 of the piezoelectric film 1 is divided into two coating surfaces 9, 10 which are electrically insulated from one another, and strip-shaped sections 4 and 5 are formed which interlock like a comb. The two separate coating surfaces 9, 10 are separated from one another by a meandering insulation 8. The strip-shaped sections 4 and 5 which interlock like a comb are combined into groups which each have their own signal outputs 6 and 7. The signal outputs 6, 7 are connected, for example, to logic input circuits of a processing circuit via amplifiers (not shown). The meandering, electrical insulation 8 can be produced in such a way that the material of the coating 2 is removed along this meandering path either by etching or mechanically. Preferably, the sum of the areas of the strip-shaped sections A is equal to the sum of the areas of the strip-shaped sections 5.

As shown in Fig. 2, the piezoelectric film 1 is arranged between two plastic plates 3 in a shield 12. This damping mat 13 performs the task of impact sound insulation. A damping mat 14 is arranged below the piezoelectric film 1 outside the shield 12.

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It may be appropriate to arrange acoustic wool 14 above this layered structure and to package the whole thing in a casing 15.

Fig. 3 shows schematically an embodiment of a sensor that is used as a breathing mat. The systematic structure is shown. The foil is divided into strip-shaped sections 4 and 5 in such a way that

&bull;j 0 ning groups are formed, with alternating strips being connected to the same output 6, 7. A separate output 6 or 7 is provided for each group, whereby this breathing mat is not a film with a meandering coating. For example, this breathing mat can be manufactured in such a way that a film with a two-sided coating is cut into strips and the second strip of a group is turned over so that the groups of alternating strips have opposite polarity. However, it is also possible to manufacture the strips in such a way that one coated side of the film has strip-shaped coating sections. These strip-shaped coating sections can be produced during the manufacturing process by an appropriate printing or vapor deposition technique. However, it is also possible to provide a homogeneous coating of a film with insulation strips by mechanical processing or by means of an etching process, which form strip-shaped sections 4 and 5 in the homogeneous coating.

An opposite polarization can be achieved by an electrical circuit, such as

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shown schematically in Fig* 4«

As shown, the electrically conductive coatings 2 and 3 of the piezoelectric foil 1 are designed in such a way that adjacent, strip-shaped sections 4a and 5a are formed. An opposite, picoelectric onslaught is produced by a special electrical connection of the individual strips ■jQ in each group &ldquor;

This connection uses the through-hole plating technique, as is common in printed circuits and the like. It can be seen that the strip section 4a at the bottom in Fig. 4 has a connection that leads to the next strip 4a in the group, namely on the other side of the foil. From there, the line then runs back to the underside of the foil.

As shown, the strips 5a are designed in such a way that this electrical line can be produced by a printing and through-plating process. On the other hand, the strips 5a are connected to one another in an equivalent manner. It can be seen that a meandering contact is guided through the piezoelectric film 1, whereby a reversal of the piezoelectric orientation takes place.

3Q The sensor shown in Fig. 5 has a piezoelectric foil 1 which is arranged between two thin plastic plates 16. This sandwich assembly

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Claims (10)

r - · r ^ ^ β «· β rt r- · re · Patent Attorneys Mi=I I KOkISK I & NX European Patent Attorneys i & Ninneiann Xantener Str. 10 D-1000 Berlin German Patent Office 8000 Munich Sr. iichael taikoaski, Dipl.-Ing. Detlef Hinnetann, Bipl.-Ing. lantener street D-IOOO Berlin 15 Telephone 030/081 81 81 * 882 68 Telex t 85 366 Your sign: Four ref. Regards: Applicant: Dr.-Ing. Herwig Freiherr v Berlin Date: Office/ofhce Bünchen Date: NyMphenburger Straße 81 19.03 D-e000 fliincÄen 19 Freephone 089/18 08 18 Telephone 5 22 263 our time: Our ref. P 45/87 III/ha .1987 Nettelhorst, 1000 1. Sensor for mechanical forces emanating from animal or human bodies, in particular impulses with a piezoelectric foil arranged on a substrate layer and having an electrically conductive coating on both sides, characterized in that 45/87.pa9 -2- the piezoelectric foil (1) is divided into strip-shaped sections (4, 5), and that these strip-shaped sections (4, 5) alternate with % each to one of two separate signal outputs (6, *' 7) are connected. 2. Sensor according to claim 1, 10 characterized in that the sums of the areas of the alternating strip-shaped sections (4, 5) are equal to each other . 3. Sensor according to claim 1 or 2, ; characterized in that 20
! one side of the film (1) has a homogeneous, electrically conductive coating and that the electrically ( conductive coating (3) on the other side is a meander-shaped insulation (8) in two comb-like j 25 interlocking, electrically insulated coating surfaces (9, 10), each of which is connected to a signal output line (6, 7) is connected. 4. Sensor according to claim 3, characterized in that 35 t * 4 4 Λ Λ* ··· ·&Igr;■·<! If ijll II ·<«· i &iacgr; » « til III · *«« ·· here it * ·· · «·&idigr;&ggr; »ilii «· · · · suffered &igr;&igr;< -3- the meander-shaped insulation (8) is designed as a strip free of coating material. 5. Sensor according to one of claims 3 or 4, at least along one edge section of the piezoelectric foil (1) a second piezoelectric foil with opposite polarity is attached, the polarity (orientation of the molecular dipoles) of which is opposite to the first foil* 6. Sensor according to claim 5, characterized in that the surface of the second piezoelectric film is substantially equal to that of the first piezoelectric film (1). 7. Sensor according to claim 1 or 2, characterized by the fact that the piezoelectric polarization of alternating strip-shaped sections (4, 5; 4a, 5a) in each group of the respective signal outputs (6, 7) connected sections (4, 5). 45/87.pa9 8. Sensor according to claim 7, characterized by the fact that the electrically conductive coating (2, 3) on each side of the piezoelectric film (1) is divided into strip-shaped, electrically separated sections (4a, 5a) and that each signal output line (6, 7) is alternately connected to the electrically conductive coating section (3, 4a) on one and (2, 4a>) on the other surface of the film. 9. Sensor according to claim 7 or 8,
characterized in that the signal output lines (7a) are meander-shaped vias (Fig. 4). 10. Sensor according to one of claims 1-9, characterized in that the piezoelectric foil (1) is inserted between two plastic plates (16) and this assembly is covered by an electrical shield (17). 45/87.pa9