TEXTILE SENSOR FOR THE DETECTION OF LIQUIDS AND TEMPERATURE, AND METHOD OF MAKING SAME

Abstract

A textile device for detecting liquids comprising a matrix fabric obtained by knitting, a first non-insulated conductive wire and a second non-insulated conductive wire knitted with the matrix fabric, a source of electric energy connected to the non-insulated conductive wires in order to create a first electric circuit and to have a potential difference between the non-insulated conductive wires, an electrical resistance measuring device configured to measure the electric resistance R in the first electric circuit. The textile device is configured in such a way that, when the non-insulated conductive wires electrically connect by means of a liquid, the electrical resistance measuring system measures a variation of electric resistance R in said first electric circuit. Furthermore, at least one insulated conductive wire is provided connected to a source of electric energy in order to create a second electric circuit.

Claims

1. A textile device for detecting liquids comprising: a matrix fabric obtained by knitting; a first non-insulated conductive wire knitted with said matrix fabric; a second non-insulated conductive wire knitted with said matrix fabric; a source of electric energy connected to said non-insulated conductive wires in order to create a first electric circuit and to have a potential difference between said non-insulated conductive wires; an electrical resistance measuring system configured to measure the electric resistance R in said first electric circuit in such a way that, when said non-insulated conductive wires electrically connect by means of a liquid, said electrical resistance measuring system measures a variation of electric resistance R in said first electric circuit; wherein at least one insulated conductive wire is provided connected to a source of electric energy in order to create a second electric circuit; said electrical resistance measuring system is arranged to measure the electric resistance R in said second electric circuit in such a way that, since said electric resistance R is function of the temperature T, when a variation of temperature T occurs at said matrix fabric, said electrical resistance measuring system measures a variation of electric resistance R in said first electric circuit.

2. The textile device for detecting liquids, according to claim 1, wherein, when said non-insulated conductive wires electrically connect by means of said liquid, said resistance R turns from an infinite value to a finite value.

3. The textile device for detecting liquids, according to claim 1, wherein said matrix fabric is a tissue at least partially able of absorbing liquids.

4. The textile device for detecting liquids, according to claim 1, wherein each of said non-insulated conductive wires comprises a plurality of branches.

5. The textile device for detecting liquids, according to claim 4, wherein said branches of said non-insulated conductive wires are arranged in parallel mesh ranks, in such a way that said non-insulated conductive wires form respective comb structures at least partially interpenetrated.

6. The textile device for detecting liquids, according to claim 1, wherein said insulated conductive wire is co-knitted with at least one of said non-insulated conductive wires.

7. The textile device for detecting liquids, according to claim 1, wherein said non-insulated conductive wires protrude from said matrix fabric, in such a way that said non-insulated conductive wires are electrically connected if located in contact with a surface containing said liquid.

8. A textile device for detecting liquids comprising: a matrix fabric obtained by knitting; a first non-insulated conductive wire; a second non-insulated conductive wire; a source of electric energy connected to said non-insulated conductive wires in order to create an electric circuit and to have a potential difference between said non-insulated conductive wires; an electrical resistance measuring device configured to measure the electric resistance R in said electric circuit; said textile device being configured in such a way that when said matrix fabric is located in contact with a liquid, said non-insulated conductive wires electrically connect by means of said liquid, and said electrical resistance measuring device measures a variation of electric resistance R in said electric circuit, said textile device characterized in that said first non-insulated conductive wire is knitted with a first face of said matrix fabric and said second non-insulated conductive wire is knitted with a second side of said matrix fabric, opposite to said first face, forming a three-dimensional “sandwich” structure wherein said matrix fabric is adapted to separate said first non-insulated conductive wire and said second non-insulated conductive wire.

9. A method for making a textile device for detecting liquids comprising: arranging a linear knitting machine comprising at least one first thread guide, a second thread guide and a third thread guide; arranging a textile wire on said first thread guide, a first non-insulated conductive wire on said second thread guide and a second non-insulated conductive wire on said third thread guide; arranging at least one insulated conductive wire on at least one among said second thread guide and said third thread guide; alternated knitting of said textile wire, of said non-insulated conductive wires and of said insulated conductive wire; co-knitting of said or each insulated conductive wire with said first non-insulated conductive wire and/or with said second non-insulated conductive wire; connecting a source of electric energy to said non-insulated conductive wires in order to create a first electric circuit and to have a potential difference between said non-insulated conductive wires; connecting said source of electric energy to said or each insulated conductive wire in order to create a second electric circuit; arranging an electrical resistance measuring device configured to measure variation of electric resistance R in said first electric circuit and in said second electric circuit.

10. The method for making a textile device for detecting liquids, according to claim 9, wherein said textile wire is at least partially able of absorbing liquids.

11. The method for making a textile device for detecting liquids, according to claim 9, wherein said non-insulated conductive wires are knitted starting at opposite sides with respect to each other of said linear knitting machine.

12. The method for making a textile device for detecting liquids, according to claim 11, wherein said branches of said non-insulated conductive wires are arranged in parallel mesh ranks, in such a way that said non-insulated conductive wires form respective comb structures at least partially interpenetrated.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0023] Further characteristic and/or advantages of the present invention are more bright with the following description of an exemplary embodiment thereof, exemplifying but not limitative, with reference to the attached drawings in which:

[0024] FIG. 1 diagrammatically shows a first exemplary embodiment of the textile device for detecting liquids, according to the present invention;

[0025] FIG. 1A shows in cross section the exemplary embodiment of the textile device for detecting liquids of FIG. 1;

[0026] FIG. 2A diagrammatically shows a perspective view of a second exemplary embodiment of the textile device for detecting liquids, according to the present invention;

[0027] FIG. 2B diagrammatically shows in cross section the exemplary embodiment of FIG. 2A of the textile device for detecting liquids, according to the present invention.

DESCRIPTION OF A PREFERRED EXEMPLARY EMBODIMENT

[0028] With reference to FIG. 1, in a possible exemplary embodiment, the textile device 100 for detecting liquids, according to the present invention, comprises a matrix fabric 105 obtained by knitting, during which a first non-insulated conductive wire 110 and a second non-insulated conductive wire 120 have been also co-knitted.

[0029] In particular, each non-insulated conductive wires 110,120 comprises a plurality of branches 112,122 arranged in parallel mesh ranks, and knitted in alternate rows, in such a way that the non-insulated conductive wires 110,120 form respective comb structures at least partially interpenetrated and in such a way to homogeneously cover the surface of the textile device 100.

[0030] The non-insulated conductive wires 110,120 are connected to a source of electric energy, in order to create a first electric circuit and to have a potential difference between the non-insulated conductive wires 110,120. Furthermore, there is present, but not shown in the figure for simplicity, an electrical resistance measuring device configured to measure the electric resistance R in the first electric circuit.

[0031] This way, when the matrix fabric 105 is located in contact with a liquid, or with a humid or wet material, the non-insulated conductive wires 110,120 electrically connect by means of this liquid, and the electric resistance measurement device measures a variation of electric resistance R in the first electric circuit.

[0032] Furthermore, the textile device 100 comprises at least one insulated conductive wire 130 also connected to a source of electric energy to create a second electric circuit.

[0033] Advantageously, the insulated conductive wire 130 can be co-knitted with at least one of the non-insulated conductive wires 110,120, so as to simplify the manufacturing process and optimize the space on the textile device 100.

[0034] In particular, the electrical resistance measuring system is configured to measure the electric resistance R also in the second electric circuit in such a way that, since the electric resistance R is function of the temperature T, when a variation of temperature T occurs at said matrix fabric (105), the electrical resistance measuring system measures a variation of electric resistance R in the first electric circuit.

[0035] This way, the textile device 100 allows both to measure the presence of humidity and a temperature variation in the vicinity of the electrical circuits, adapting to numerous uses, such as the monitoring of these parameters on the person or inside environments.

[0036] In particular, the matrix fabric 105 can be at least partially capable of absorbing liquid. In this case, the matrix fabric can absorb the liquid or the humidity and allow the electric connection between the non-insulated conductive wires 110,120.

[0037] In any case, both with permeable and waterproof matrix fabric, the device is also capable of detecting a liquid contained in an external damp, or wet, fabric placed in contact with the non-insulated conductive wires. Therefore, the device is capable of detecting a liquid leak even before it is moistened or wet itself.

[0038] Furthermore, the device is able both to detect the sudden presence of a liquid or a wet tissue, detecting a variation of the electrical resistance R that passes from an infinite value (open electric circuit) to a finite value (closed electric circuit), and to detect a variation in humidity, detecting a variation in the electrical resistance value R which passes between two finite values.

[0039] Furthermore, in case there are a plurality of first and second non-insulated conductive wires, the first conductive wires can be connected together with a first pole of the electrical resistance measuring device and, similarly, the second conductive wires can be connected together with a second pole of the electrical resistance measuring device.

[0040] With reference to FIG. 1A, in an exemplary embodiment of the invention, the non-insulated conductive wires 110,120 are knitted creating a higher thickness than the matrix fabric 105, in order to protrude with respect to it in thickness.

[0041] This embodiment makes it possible to facilitate contact between the non-insulated conductive wires 110, 120 and a surface 200 whose humidity is to be detected and which rests on the textile device 100 without sufficient pressure to fully come into contact with the matrix fabric 105. For example, this embodiment is particularly suitable to be used for clothing or linen in order to measure the conductivity of a user's skin and, in particular, his level of perspiration (Galvanic Skin Response).

[0042] With reference to FIGS. 2A and 2B, in an alternative exemplary embodiment of the textile device 100, the non-insulated conductive wires 110,120 are knitted with the textile wire 106 at opposite faces 105a,105b of the matrix fabric 105, in order to form a three-dimensional “sandwich” structure where the matrix fabric 105 is adapted to separate the first non-insulated conductive wire 110 and the second non-insulated conductive wire 120.

[0043] The foregoing description some exemplary specific embodiments will so fully reveal the invention according to the conceptual point of view, so that others, by applying current knowledge, will be able to modify and/or adapt in various applications the specific exemplary embodiments without further research and without parting from the invention, and, accordingly, it is meant that such adaptations and modifications will have to be considered as equivalent to the specific embodiments. The means and the materials to realise the different functions described herein could have a different nature without, for this reason, departing from the field of the invention. it is to be understood that the phraseology or terminology that is employed herein is for the purpose of description and not of limitation.