DE3836712A1 - Highly flexible large-area sensor mat - Google Patents

Abstract

Published without abstract.

Description

The invention relates to a thin, large-area and highly flexible sensor mat, which is interspersed with conductive elements. The sensory function The mat is created by the evaluation of electrical properties (Resistance or conductivity, capacitance, impedance, resonance frequency) the distributed in the area vanes (electrodes).

The sensor mat according to the invention can be used, for example, as contact-sensitive Protective covering (fabrics) used in occupational safety (machine protection) become. Similar application possibilities are in the object security or in the recording (counting) of passenger or vehicle movements given. In addition, the construction can also be called moisture-sensitive Element in the sense of a large-area leak detector for Monitoring of equipment, piping or machinery are used. Also in the medical field, appropriate sensor mats can be used in Sterile design can be used as a disposable article, for example in Connection with equipment for monitoring for incontinence (bedwetting).

In principle, such sensor mats and associated evaluation circuits known. The subject of this invention is a particularly advantageous one Variant in the construction of the sensor mat. The advantages of the invention Construction concern on the one hand the electrical properties the sensor mat and on the other hand used for the production Manufacturing engineering. In this way, new application areas for the Sensor mats are developed.

The basic structure of the sensor mats under discussion here is shown in FIG . The points [A] and [B] are contact points for connecting the sensor mat to an associated evaluation electronics (monitor). Between these two contact points, the electrical properties of the sensor mat are evaluated. From the contact points [A] and [B] initially leads each associated longitudinal conductor 1 and 6 as a busbar to the existing in large numbers transverse conductors 2 and 5 respectively. The cross-conductors must be connected (electrically) alternately to the contact points [A] and [B] so that the following contacting scheme is repeated within the sensor mat: cross-conductor 2 to contact point [A] and cross-conductor 5 to contact point [B] . As a sensorically active surface here is the framed area 7 to see, so only that area in which the transverse conductors 2 and 5 mesh with each other in a comb.

In a number of applications, it is desirable to make the sensor-sensitive surface 7 of a sensor mat very large, ie to extend it as far as possible to several square meters. In practice, however, certain (physical) limits are set here. The achievable maximum size is particularly related to various design details of the mat. It is therefore crucial to define and, if necessary, overcome the limiting factors.

In order to illustrate these phenomena, an event to be detected (contact, leak) on a large-area sensor mat is supposed to act on a point-like point of action 8 in a model example. With reference to FIG. 1, it can be seen that the effect that is accessible by measurement - which arises primarily at the point identified by reference numeral 8 - is connected to the contact points [A] and [B] via a long conduction path. In the present case, this means that the measuring current emanating from [A] within the sensor mat must first flow over the longitudinal conductor 1 , the connection point 3 and one of the transverse conductors 2 before it reaches the action point 8 . From there, the current must again flow via one of the opposite transverse conductors 5 , the connection point 4 and the longitudinal conductor 6 to the second contact point [B] .

In a thin, highly flexible sensor mat typically come relatively small conductor cross sections in a delicate arrangement are used. This then means that even the guiding elements of a large-area mat by itself have a significant electrical resistance. This proportion of resistance brings with it a number of problems in practice yourself. The resistance of the guiding elements must therefore always be considered, d. H. electronically compensated or (better) by a cheap Design of the vanes are kept at a very low level.

Fig. 2 shows the electrical equivalent circuit diagram of a spatially extended sensor mat. The conduction and contact resistances caused by the various guide elements and the associated connection points are symbolized here by the two series resistances Rs . In addition to these line-induced series resistances, significant parallel resistances Rp also occur in large-area structures in practice, which depend on the insulation value of the respective carrier material (tissue, etc.) and possibly also on the relative humidity.

In the case of an evaluation with alternating current, the parasitic capacitances Cp that arise between the conductor structures must also be taken into account. The use of alternating current is necessary, for example, in the detection of liquids in order to eliminate electrolytic polarization effects at the electrodes.

It can be seen from the equivalent circuit diagram of FIG. 2 that a local action 8 on the sensor mat-identified as an electrical change Rx, Ry, Cz -can only be detected with sufficient certainty at the contact points [A] and [B] if the associated with the action change in the electrical values in a favorable ratio to the already existing series resistances Rs , the parallel resistance Rp and the parasitic capacitance Cp .

The Rs, Rp and Cp requirements for spatially small sensor mats (a few dm²) can usually be fulfilled without any problems. However, if a large spatial extent of the sensor mat is desired, then the said working conditions can only be achieved by means of special techniques. In the selection of manufacturing techniques is also to be considered that the industrial production of large-scale sensor mats can be economically interesting only with simple, ie cost-optimized method.

The planar processing of conductive elements with the aim of obtaining sensory surfaces is known in principle. For example, the structures of FIG. 1 (using conductive pastes) can be prepared by screen printing. But even with the use of (expensive) screen-printed pastes filled with precious metal, unreasonably high series resistances usually arise with large mats. Furthermore, it has been found that the conductor structures applied by the screen printing process already receive numerous interruptions at low mechanical stress (wrinkling).

Another production technique could be, for example, to produce a textile structure with conductive elements in the weaving process. With the classical weaving technique, however, either only longitudinal or only transverse conductors can be incorporated (see FIG. 1). So far, no industrially feasible solution has been specified, which makes it possible to contact the parallel drawn threads (alternately in the sense of a comb structure). Any subsequently created connection point would then also have to be regarded as a weak point in terms of quality assurance. In a weaving process, therefore, it would be necessary to carefully test what reliability can be expected from such a sensor mat under real-world conditions.

An elaborate solution would be the sewing of conductive elements conceivable. However, this technique - even when using automatically controlled Industrial sewing machines - very time consuming, as the entire route all guide elements must be moved from the sewing head. This route is located usually on the order of more than 100 meters per square meter Sensor surface. Sewing techniques are therefore only limited to industrial production large sensor mats suitable.

The invention has for its object to provide a thin, large-scale and highly flexible sensor mat whose guide elements contact permanently, reliably and with low electrical resistance according to the comb scheme of FIG . The design principle should allow the use of efficient and cost-effective production techniques. It should be particularly suitable for continuous production on the fly band.

The object is achieved in that the sensor mat in a layer structure is made. Located inside the layer structure a planar arrangement of electrically conductive elements (Wires, foils, fibers). These guide elements serve as measuring electrodes. When Carrier or cover material can be inexpensive, non-conductive cover layers (Fabric, fleece, felt, cardboard, paper, foil) used in the form of rolls become.

The planar arrangement of electrical conductors (measuring electrodes) is essentially of a bevy of thin, parallel clamped vanes (Wires, strands, foil strips, fibers or threads) formed. In a  Endless manufacturing, for example, the direction of this leader would at the same time represent the running direction of the machine.

A practical problem now is the alternate contacting of the conductor array according to the reproduced in Fig. 1 scheme. Fig. 3 shows how the (here longitudinal) transverse conductors 2 and 5 can be contacted according to the principle of the invention: For contacting band-shaped contact strips 10 are used, which take over the function of the longitudinal conductors 1 and 6 of FIG .

The contact strips 10 consist of an insulating carrier tape on which a conductive structure is laminated as a contact band on both sides. An alternating contacting of the transverse conductors 2 and 5 is now achieved in that the transverse conductors run alternately above and below the contact strip 10 . In this way, the overhead contact band connects all provided with the reference numeral 2 transverse conductor and thus establishes the connection of the transverse conductor 2 to the contact point [A] ago. In an analogous manner, all cross conductors provided with the reference numeral 5 are detected on the back contact band and connected to the contact point [B] located on the rear side of the contact strip 10 .

The arrangement of conductors described above is a complete image of the comb-shaped interdigitated electrode pattern according to the scheme of Fig. 1. Finished sensor mats can now be easily prepared by the spanned electrode assembly together with the associated contact strips 10 between two cover layers Tissue, fleece, felt, cardboard, paper, foil or the like is fixed to one another (embedded, laminated, welded).

FIG. 4 shows a device suitable for the continuous production of the sensor mats according to the invention: a new contact strip 10 is inserted at regular intervals between an upper group of transverse conductors 2 and a lower group of transverse conductors 5 at the point indicated by an arrow 23 . This bar is transported by the continuing wire coulters to a pair of rollers 22 (calender). On the pair of rollers 22 , the fixing (embedding) of all guide elements is then carried out continuously with the aid of the cover layers 20 and 21 supplied as roll goods.

With the help of the pair of rollers, the entire arrangement is permanently fixed. Depending on the application, the adhesion of the outer layers to one another can be achieved with the aid of spray adhesives, hot melt adhesives or by welding. In this way, the product 24 initially arises as a running tape. The individual sensor mats can then be continuously punched out of the band in any desired form. For each mat, a separate contact strip 10 is provided in the fabric (band).

To illustrate the contacting principle according to the invention, an embodiment of a contact strip 10 is shown in cross section in FIG . A 20 mm wide paper tape forms the insulating carrier 30 here . Along this carrier contact bands 32 are laminated on both sides. They consist in this case of a made by the addition of stainless steel fibers made textile tape. This band is elastic and has the dimensions of about 2.0 × 0.3 mm. As cross conductors 2 and 5 are stainless steel wires of about 0.1 mm in diameter. These wires are clamped in parallel at intervals of 10 mm.

If the contact strip 10 is inserted as shown in FIG. 3 or 4 between the wire coulters 2 and 5 , in the example described here as an additional measure on both sides nor a thin tin foil 34 is added in the length of the contact strip. The tin bands 34 enclose the stainless steel wires acting as transverse conductors. In this way, all the wires touch both upper side and underside a belonging to the longitudinal conductor conductor structure. This two-sided inclusion ensures a very high contact reliability to the cross-conductors 2 and 5 and ensures along the longitudinal conductor for minimum series resistance to the contact points [A] and [B] .

Depending on the application, both the contact strips 32 used in this example and the corresponding tin foils 34 could be substituted by other guide elements with similar electrical and mechanical properties. For example, one of the two elements 32 and 34 could also be replaced by a conductive elastomer if the respective opposing element has a higher (ie metallic) conductivity. Essential for the inventive idea is the all-round and elastic embedding of the transverse struts 2 and 5 .

In order to keep the parasitic capacitance within the contact strip 10 low, it is advantageous if the front and rear side mounted on the insulating substrate 30 contact bands 32 are not directly opposite, but - as shown in Fig. 5 - are sufficiently offset from each other.

As cover layer 20 or 21 , a nonwoven coated with hotmelt adhesive is used in the example described here. The use of this commercial material as a roll product leads to sensor mats with an extremely low cost level per unit area.

In practice, with the contacting method according to the invention effortless error rates of better than 1 faulty contact per 10,000 contact points reached. Experiments have shown that the high contact security also under the influence of environmental influences and strong mechanical Stress is fully retained.

On a sensor mat manufactured in accordance with the above description in dimensions 1 m × 1 m, the following electrical data were determined:

Series resistance in the longitudinal conductor: Max. 1 ohm Series resistance in the cross conductor: Max. 50 ohms Parallel resistor: about 100 MOhm Parallel resistor: about 100 pF

From the present measurements it follows that after the here described Even extremely large sensor mats can be produced. With an effective sensor area of, for example, 1000 m², series resistors are used in the order of 1 kOhm and a parallel resistor in of the order of 100 kOhm. A mat with these dimensions could still be easily evaluated electrically - for example in function as a leak detector for a chemical plant.

For sensor mats with smaller dimensions alone allows the application the production process according to the invention in high quantities a significant cost advantage compared to conventional manufacturing techniques. For the sensor mats in the design according to the invention are therefore also given numerous applications in the consumer goods industry.

Claims (4)

1. Thin, highly flexible sensor mat, interspersed with conductive elements, which act as measuring electrodes, characterized in that the conductive elements consist essentially of a family of thin, parallel-spanned wires or threads, which are between two cover layers of fabric, fleece, felt, Cardboard, paper, foil o. The like. Fixed (embedded, laminated, welded) are. 2. Sensor mat according to claim 1, characterized in that a reciprocal, comb-shaped contacting of the parallel guide elements 2 and 5 by means of a transversely inserted contact strip 10 takes place. 3. Sensor mat according to claim 1 or 2, characterized in that the contact strip 10 is composed of an elastic, band-shaped Isolierstoff- carrier 30 and two laminated, elastic contact strips 32 . 4. Sensor mat according to one of claims 1 to 3, characterized in that in addition to the contact strip 32, a flexible metal foil 34 is guided along the contact strip 10 in order to optimize the contact resistance of the wires or threads is enclosed on both sides by guide elements.