WO2018091620A1

WO2018091620A1 - Sensor thread structure

Info

Publication number: WO2018091620A1
Application number: PCT/EP2017/079522
Authority: WO
Inventors: Heiko Kochmann
Original assignee: Amann & Söhne GmbH & Co. KG
Priority date: 2016-11-18
Filing date: 2017-11-16
Publication date: 2018-05-24
Also published as: DE112017005836A5; DE102016122272A1

Abstract

The invention relates to a sensor thread structure for sensing moisture in an extensive object region, comprising an electrically conductive inner electrode thread (12), an inner sheath (14), which encloses the inner electrode thread (12), an electrically conductive outer electrode thread (16), which extends outside the inner sheath (14) along the inner electrode thread (12), and a moisture-permeable outer sheath (18), which jointly surrounds the inner sheath (14) and the outer electrode thread (16), wherein the electrical resistance or the electrical capacitance between the electrode threads (12, 16) can be varied by the influence of moisture on the inner sheath (14).

Description

Sensorfadengebilde Description

The invention relates to a sensor filament for moisture detection in an extended object area such as a vehicle cavity or a building. The invention further relates to a circuit arrangement for measuring moisture with a sensor filament formation.

DE 10342787 A1 mentions the use of an electrically conductive yarn as a moisture sensor. There it is proposed that the yarn should comprise an elastic core thread, at least one electrically conductive thread wound around the core thread and at least one binding thread wound around the core thread. The focus is on limiting the extensibility of the electrically conductive composite yarn by the Umwindefaden. Details of the structure of only incidentally mentioned moisture sensor are not disclosed. Proceeding from this, the object of the invention is to improve the textile sensors known in the state of the art and to provide a linear sensor structure which can be laid without difficulty even in a difficult-to-reach or extended object area, being insensitive to damage and easy detection of moisture or water access to the structure allowed.

To solve this problem, the feature combination specified in claim 1 or 13 is proposed. Advantageous embodiments and modifications of the invention will become apparent from the dependent claims.

The invention is based on forming two torsion-free linear electrodes by special cladding as a moisture sensor. Accordingly, it is proposed according to the invention that the sensor filament formation comprises an electrically conductive inner electrode thread, an inner jacket electrically insulating the inner electrode thread, an electrically conductive outer electrode thread running outside the inner jacket along the inner electrode thread, and a coextensive inner jacket and the outer electrode thread, moisture-permeable outer sheath, wherein the electrical resistance or the electrical capacitance between the electrode threads by moisture influence on the inner shell is variable. By the inner jacket so the sensitivity can be suitably influenced while the outer jacket provides protection against unwanted contamination or mechanical damage. Overall, a largely direction-independent flexible structure is defined, which can also be easily moved around corners. In principle, the construction of the structure allows unproblematic, virtually endless processing.

In order to allow the passage of moisture, it is advantageous if the inner and / or outer jacket is provided with a plurality of moisture-permeable openings.

Such openings can be easily created and dimensioned, in particular as thread spaces, when the inner and / or outer sheath is formed as a tubular textile structure. A further improvement in this direction results from the fact that the inner and / or outer sheath is formed as a braiding, wrapping, or Umwin- formation of an electrically non-conductive thread material.

In order to achieve the desired sensor properties, it is advantageous if the inner and / or outer sheath is formed from synthetic fibers, natural fibers, mineral or inorganic fibers, or mixtures thereof. In order to influence the sensitivity in the desired manner, it is advantageous if the inner jacket consists of a moisture-absorbing material. With regard to the desired flexibility and electrical properties, it is favorable if the electrode threads are selected from the group wire or strand of metal, in particular of brass or copper; carbon fiber; metal-coated mono- or multifilament. Advantageously, the electrode threads run side by side without mutual twisting, so that consistent properties are achieved over a short period of time with little use of material.

To set a desired stiffness, it is also possible that in addition to the inner electrode thread runs an additional core thread.

A particularly advantageous embodiment provides that the outer casing is provided all around with a self-adhesive adhesive structure. This considerably simplifies and reliably ensures the intended positioning in an object area.

In this context, it is also advantageous if the self-adhesive structure consists of a pressure sensitive adhesive, preferably based on acrylate. It is understood that the adhesive structure should allow the passage of moisture as completely as possible, for example, by only the thread material of the outer shell is coated adhesive.

In order to simplify the connection of a measuring device, it is expedient for the electrode threads to have at least one of their ends an externally accessible contact point led out of the sensor body. The invention also relates to a circuit arrangement for measuring moisture with a sensor filament structure according to the invention and a measuring unit connected to one end of the electrode filaments for a resistance measurement or capacitive measurement between the electrode filaments. Hereby, the advantages listed above can be achieved equally.

In order to carry out a moisture monitoring, it is advantageous if an evaluation unit acted upon by a signal of the measuring unit is configured to determine the presence of moisture from a signal change or signal level.

A simple control function can be realized by connecting a test unit for checking the function of the electrode threads at their two ends for a measurement of the respective contact resistance.

In the following the invention will be explained in more detail with reference to the embodiment shown schematically in the drawing. Show it:

1 shows a circuit arrangement for measuring moisture with a sensor filament formation in a partially broken-perspective, partly schematic view; Fig. 2 is a circuit diagram of the circuit arrangement.

The sensory thread structure 10 shown in the drawing comprises a linearly elongated, electrically conductive inner electrode thread 12, an inner sheath 14 electrically insulating the inner electrode thread 12, an electrically conductive outer electrode thread 16 running next to the inner electrode thread 12 outside of the inner sheath 14 and one the inner shell 14 and the outer This filament structure 10 is characterized in that the electrical resistance or the electrical capacitance between the electrode filaments 12, 16 is variable by the influence of moisture on the inner jacket 14.

For moisture detection, the thread structure 10 can be connected at one end via contact points 20, 22 at its electrode threads 12, 16 to a measuring unit 24 for a resistance or capacitance measurement, wherein an evaluation unit 26 acted upon by a signal of the measuring unit 24 is adapted to a signal change or signal height to determine the presence of moisture at least qualitatively. In this case, the linear elongated thread structure 10 can be laid in a difficult to reach and / or extended object area 28, for example in a cavity of a vehicle or a building, to carry out a moisture monitoring, for example, for a tightness check or checking the drying condition.

In order to simplify the positioning of the sensor structure 10 when it is laid, the outer shell 18 can be provided with a self-adhesive adhesive structure 30. This adhesive structure 30 may suitably consist of acrylate-based coating of a pressure-sensitive adhesive.

While maintaining a desired flexibility, the electrode threads 12 16 may be formed of a metal wire, in particular of brass.

Moisture detection in the thread formation 10 is made possible by providing the inner and outer sheaths 14, 18 with a plurality of moisture-permeable openings 32. These are created as thread gaps by the inner and outer sheaths 14, 18 being designed as a textile tube 34. In the example shown, this is a braid of an electrically non-conductive thread material 36 from Polyester or polyamide provided. The laying of the threads is not perpendicular as in weaving, but under diagonal crossing relative to the sensor longitudinal axis. The compression of the gaps can be easily adjusted.

While the outer sheath 18 should be easily permeable to moisture or water, it is conceivable that the inner sheath 14 also absorbs moisture and for this purpose consists of a suitable material, such as natural fibers such as cotton.

Due to the penetration of moisture into the interstices 32 of the inner shell 14 or in its thread material, the electrical conductivity between the electrode threads 12, 16 is increased, which can be detected by a resistance measurement. At the same time, the electrical capacitance between the electrode threads 12, 16 also increases. The cause here is the very high dielectric constant of the water in comparison to the insulating thread material in the dry state. Also, by measuring the capacitance, the moisture content of the inner jacket 14 can be easily determined. 2 shows a section of the thread structure 10 in a schematic cross section with a measuring unit 24 suitable for resistance or capacitance measurement. In order to enable functional testing of the electrode threads 12, 16, for example, for breakage, a testing device 24 'can be used at the respective thread ends for a electrical continuity test are connected.

Depending on the application, the thread structure 10 can be adjusted appropriately. The flexibility can be influenced, above all, by the rigidity of the electrode threads 12, 16. For this purpose, a flexible core in the form of a core thread that runs parallel to the inner electrode thread 12 can also be set. Materials for this additional core are preferably monofilaments of synthetic fibers. In order to adjust the sensitivity, the layer thickness and the Fadenmatenal the inner shell 14 can be selected appropriately. The response can be improved by increasing the capillary action of the inner jacket 14.

Claims

Sensor filament formation for detecting moisture in an extensive object area, for example in a vehicle or building, with a linearly extending, electrically conductive inner electrode thread (12), an inner jacket (14) surrounding the inner electrode thread (12), one outside the inner jacket (14) the electrically conductive outer electrode thread (16) extending in the inner electrode thread (12) and a moisture-permeable outer jacket (18) enveloping the inner jacket (14) and the outer electrode thread (16), wherein the electrical resistance or the electrical capacitance between the electrode threads (16) 12, 16) is variable by the influence of moisture on the inner casing (14).

Sensor filing structure according to claim 1, characterized in that the inner and / or outer sheath (14,18) is provided with a plurality of moisture-permeable openings.

Sensor sheet formation according to claim 1 or 2, characterized in that the inner and / or outer sheath (14,18) is formed as a tubular textile structure.

Sensor filament formation according to one of claims 1 to 3, characterized in that the inner and / or outer sheath (14,18) is formed as braiding, wrapping, or winding of an electrically non-conductive thread material.

Sensor filament structure according to one of claims 1 to 4, characterized in that the inner and / or outer sheath (14,18) of synthetic fibers, natural fibers, mineral or inorganic fibers, o- mixtures thereof is formed.

6. sensor fabric formation according to one of claims 1 to 5, characterized in that the inner jacket (14) consists of a moisture-absorbing material.

Sensor filament formation according to one of claims 1 to 6, characterized in that the electrode filaments (12, 16) are selected from the group wire or strand of metal, in particular of brass or copper; carbon fiber; metal-coated mono- or multifilament.

Sensor filament formation according to one of claims 1 to 7, characterized in that the electrode filaments (12, 16) run side by side without mutual twisting.

Sensor thread formation according to one of claims 1 to 8, characterized in that in addition to the inner electrode thread (12) an additional core thread is provided for setting a desired rigidity.

Sensor filing structure according to one of claims 1 to 9, characterized in that the outer casing (18) is provided all around with a self-adhesive adhesive structure (30).

Sensor thread formation according to one of claims 1 to 10, characterized in that the self-adhesive structure (30) consists of a pressure-sensitive adhesive, preferably based on acrylate.

Sensor filament formation according to one of claims 1 to 1 1, characterized in that the electrode filaments (12, 16) have at least one of their ends an externally accessible contact point for connecting a measuring unit (24). Circuit arrangement for measuring moisture with a sensor filament formation (10) according to one of the preceding claims and a measuring unit (24) connected to one end of the electrode filaments (12, 16) for a resistance measurement or capacitive measurement between the electrode filaments (12, 16).

Circuit arrangement according to Claim 13, characterized by an evaluation unit (26) acted upon by a signal of the measuring unit (24), which is set up to detect the presence of moisture from a signal change or signal level.

Circuit arrangement according to claim 13 or 14, characterized in that a test unit (24 ') for checking the function of the electrode threads (12,16) is connected at both ends for a measurement of the respective volume resistance.