FR2958578A1 - METHOD OF FIXING A SURFACE ELEMENT OF A FABRIC AND FABRIC THUS OBTAINED - Google Patents

Abstract

This method of fixing an element (10) on the surface of a fabric (12) consists in: ▪ encapsulating the element (10) in a hot-melt material (14, 16); ▪ placing the element thus encapsulated on the surface of the fabric (12); and ▪ jointly applying pressure (18) and energy (20) to at least a portion of the heat fusible material so as to partially or completely melt said portion.

Description

TECHNICAL FIELD OF THE INVENTION The present invention relates to the field of laying elements on the surface of a fabric and finds particular application in the field of clothing. says "smart", that is, clothing incorporating electronic features.

STATE OF THE ART Clothes incorporating electronic functionalities, such as, for example, physiological sensors, temperature control means, etc., are known from the state of the art.

Usually electronic components, such as sensors, microprocessors and their associated connectors are sewn or glued directly onto the fabric of the garment, inserted into a lining of the garment, or held on the surface of the garment by a piece of sewn fabric.

The material used to incorporate the components onto or into the garment is therefore usually thick and loose some of its flexibility. In addition, in order to protect the components against external aggressions, and particularly moisture, it is necessary to provide additional protection making the manufacturing process complex, or to provide a garment made of impermeable material, which limits the possible choice of clothing that can be instrumented.

SUMMARY OF THE INVENTION

The object of the present invention is to solve the aforementioned problems by proposing an alternative method of laying an element on the surface of the fabric, whatever the nature of this fabric, while providing protection for the element, and without that the material used for the installation of the element does not imply by itself a significant loss of the flexibility of the fabric.

To this end, the object of the invention is a method of attaching a surface element of a fabric, comprising: encapsulating the element in question in a heat fusible material; placing the element thus encapsulated on the surface of the fabric; and simultaneously applying pressure and energy to at least a portion of the heat fusible material so as to fully or partially melt said portion.

In other words, the element is embedded in a material which, upon melting, will both impregnate into the fibers of the fabric to maintain the element on the surface of the fabric and form a pocket or protective sheath for the element. In addition, the amount of hot melt material needed to achieve these two functions is minimal, this amount does not imply a loss of flexibility of the fabric.

Advantageously, the encapsulation of said element consists in inserting the latter between two films of thermofusible material. Alternatively, the encapsulation can be carried out by covering said element with fibers made of thermofusible material.

According to the invention, the joint application of the pressure and the energy can be carried out on the entire surface of the assembly formed of the element and the hot-melt material. This operation can be performed in combination with a non-hot melt material, to prevent deformation of the support during cooling (curling).

According to one embodiment of the invention, using two films of thermofusible material for the encapsulation of the element, the films in question have an area greater than that of said element (46), and the joint application of the pressure and energy is performed on portions of films not superimposed on the element so as to form a pocket or sheath therefor. The applied energy may be of a thermal or ultrasonic nature.

The subject of the invention is also a fabric incorporating on its surface an element fixed or attached according to the aforementioned method. The element thus fixed may be an elongated electrical conductor, in particular a net of conductive fibers. BRIEF DESCRIPTION OF THE FIGURES

The invention will be better understood on reading the description which follows, given solely by way of example, and made with reference to the appended drawings, in which like references designate identical elements or similar operation, and in which: FIG. 1 illustrates a first embodiment of a method according to the invention applied to the bonding of an electrical conductor; FIG. 2 illustrates a second embodiment of a method according to the invention applied to the bonding of an electrical conductor; Figures 3 and 4 illustrate a third embodiment of a method according to the invention applied to the bonding of an electrical conductor; and FIG. 5 illustrates a schematic sectional view of the fabric obtained at the end of the third embodiment of the method. DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 illustrates a first embodiment of a bonding of a deformable, elongate electrical conductor 10, for example a thread of conductive fibers or a conductive wire, to the surface of a fabric 12.

The fabric 12 may be of any type and of any kind, and for example made of natural fibers, such as cotton fibers for example, and / or of synthetic fibers, such as polyester fibers, and has any reinforcement ( canvas, twill, etc ...). A first hot melt film 14 is laid on the surface of the fabric 12, for example by means of an automated gripper arm system. The electrical conductor 10 is then placed in the center of the film 14, then a second hot-melt film 16 is placed on the conductor 10 so as to cover the latter and at least partially, but preferably completely, the first film 14.

The films 14 and 16 are for example made of polymer, such as for example polyethylene, polyurethane, ethylene-vinyl acetate. The thicknesses of the films 14 and 16, which are not necessarily identical, are advantageously between 35 micrometers and 50 micrometers. Such thicknesses allow both bonding and effective protection of the conductor 10 for a minimal amount of material. 3 A cylindrical flat wheel 18 and a cylindrical sonotrode 20 are disposed on either side of the fabric 12, the flat wheel 18 being pressed by a pneumatic cylinder against the sonotrode 20 in the direction indicated by the arrow 22. The cooperating assembly formed of the wheel 18 and the sonotrode 20 then moves by robotic arms along the fabric 12 in the direction indicated by the arrow 24, or this set is fixed and the fabric 12 is pulled in the opposite direction to that indicated by the arrow 24, so as to jointly apply a pressure and ultrasonic energy on the entire surface of the film 16.

In this way, rolling bonding is obtained. The films 14 and 16 melt under the action of the sonotrode 20. The first film 14 impregnates the fabric 12 and the second film 16 merges with the first film 16. The driver 10 is thus glued to the surface of the fabric 12, while by being sheathed over its entire surface area by the thermofusible material constituting the films 14 and 16.

Alternatively, the laying of the films 14, 16 and the conductor 10 is carried out progressively as the assembly formed by the wheel 18 and the sonotrode 20 or as the fabric 12 is drawn. .

Advantageously, the conductor 10 and the films 14 and 16 are preassembled by a system similar to that of Figure 1 but without a textile support and are for example in the form of a ribbon wound around a coil, thus avoiding to provide devices for aligning these elements during bonding and also simplifying the manufacturing process.

FIG. 2 illustrates a second embodiment of the bonding method according to the invention.

The second embodiment differs from the first embodiment in that the films 14 and 16 are replaced by a covering of the conductor 10 by the hot melt material, the conductor 10 being covered by fibers of hot melt material covered with gimped material. ie, wrapped or braided around the driver.

The embodiments just described involve in particular the application of pressure and energy to the element to be bonded to the surface of the fabric.

This therefore implies that said element supports without deterioration the pressure and the energy applied to it. However, this is not the case for all the elements, such as for example electronic chips or MEMS components (for the acronym "micro electro mechanical systems"). Similarly, by putting pressure on the element, the latter in turn presses on the fabric itself. The element is preferably chosen so that the pressure it exerts on the fabric does not damage the latter. For example, the first two embodiments are particularly suitable for elements that are initially flat or that are deformable and become flat when they are pressed, such as, for example, a ribbon of fibers.

A third embodiment of the invention will now be described, in connection with FIGS. 3, 4 and 5, avoiding such drawbacks, that is to say, not likely to damage the element to be glued and / or the fabric.

FIG. 3 illustrates a device implementing this third embodiment, FIG. 4 a sectional view of said device and FIG. 5 a sectional view of the result obtained by this third embodiment. In this embodiment, an assembly 40 of a first and a second film 42, 44 of heat fusible material encapsulating an element 46 to be bonded to the surface of the fabric 10 is made. This assembly 40 is similar to the assembly of the films 14, 16 and the conductor 10 of the first embodiment. It is made directly on the fabric 12 or 25 preassembled in the form of a ribbon wound on a dispensing system such as a coil 48 for example.

The element is for example an electrical conductor, a sensor, or an actuator, the element being in the example of FIGS. 3 to 5 an elongated electrical conductor 30 similar to the conductor 10 of the first and second embodiments.

The heat-fusible films 42 and 44 have a surface greater than that of the element 46 so as to have edges 50, 52.

A cylindrical wheel 54 is also provided in cooperation with a sonotrode 56 on which it is pressed in the direction of the arrow 58. The wheel 54 also has a circumferential recess 60 in which is housed the element to be glued 46 when the assembly formed of the wheel 54 and the sonotrode 56 moves in the direction of the arrow 24, or when the fabric moves in the opposite direction to that indicated by this arrow.

Advantageously, the sonotrode 56 comprises a similar recess 62, so as not to apply ultrasonic energy to the element 46 during bonding.

In this way, only the edges 50 and 52 of the heat fusible films 40, 42 are subjected to pressure and ultrasonic energy. The edges 50 and 52 melt and fuse to bond the element 46 to the surface of the fabric 12, while forming a protective pocket or sheath 64 of the element 46 (FIG. 5).

It has been described the joint application of pressure and ultrasonic energy. Alternatively, a thermal energy is used, for example by means of a heating element. Ultrasonic energy is however preferred because it can be located only where it is desired to bond. It therefore modifies the material only at this location, unlike the thermal energy that diffuses and thus makes it difficult to precisely control the location of its application.

Likewise, a thermofusible polymer material has been described. Other types of material may be provided and / or the material, and especially the films, may be made of multilayer. This material can thus fulfill several functions (mechanical protection, chemical protection, protection against moisture, electromagnetic shielding, ....). Furthermore, a non-heat fusible element can be used to facilitate the installation and to avoid deformation of the material. support, better known as 25 curl.

Similarly, it has been described the bonding of electrical or electronic components to the surface of the fabric. Other types of elements may be glued, such as, for example, nitinol wires, i.e., a titanium-nickel based shape memory alloy, to modify the properties of the fabric. .

Claims (9)

REVENDICATIONS1. A method of attaching an element (10, 46) to the surface of a fabric (12), comprising: encapsulating the element (10, 46) in a hot melt material (14, 16; 30; 40, 42) ; placing the element thus encapsulated on the surface of the fabric (12); and jointly applying pressure (18; 54) and energy (20; 56) to at least a portion of the hot melt material so as to partially or totally melt said portion. A method of attaching an element (10, 46) at the surface of a fabric (12) according to claim 1, wherein the encapsulation comprises inserting the element (10) between two films (14, 16, 40, 42) of hot melt material. A method of attaching an element (10, 46) on the surface of a fabric (12) according to claim 1, wherein the encapsulation comprises covering the element (10) with fibers of thermofusible material. 4. Method for fixing an element (10, 46) on the surface of a fabric (12) according to one of claims 1 to 3, wherein the joint application of pressure and energy is carried out on the entire surface of the assembly formed of the element (10) and the hot-melt material (14, 16; 30). A method of attaching a surface member (10, 46) of a fabric (12) according to claim 2, wherein the films (40, 42) have an area greater than that of the element (46). , and in that the joint application of the pressure and the energy is carried out on portions (50, 52) of films not superimposed on the element (46) so as to form a pocket (60) for this this. A method of attaching an element (10, 46) to the surface of a fabric (12) according to any one of the preceding claims, wherein the applied energy is thermal energy. A method of attaching an element (10, 46) on the surface of a fabric (12) according to one of claims 1 to 5, wherein the applied energy is ultrasonic energy. 8. Fabric comprising an element bonded or attached to its surface according to the method according to any one of the preceding claims. 9. The fabric of claim 8, wherein the element is an elongated electrical conductor, including a net of conductive fibers.