Patent Description:
Such trim or lining parts include non-restrictively dashboards, door panels, central console panels, interior roof linings, trunk carpets, etc..

The aimed functions, including for example heating, lighting, sensing, detecting, receiving, transmitting, etc.. , provide information and comfort enhancing services to users, drivers and/or passengers, and often require a connection to a power source or an electronical device for their activation or operation.

In this context the invention concerns a multi-layered self-supporting 3D shaped trim part including at least one functional element and its process of manufacturing.

The invention is more specifically directed towards nonplanar so-called structural "surface" parts, structural lining, covering parts, i.e., parts which have a small thickness compared to their surface extension and consists primarily in self-supporting, preferably substantially at least locally rigid, parts having a nonplanar, preferably 3D, shape.

A general underlying problem resides in the integration of the functional element(s) within the trim part as close as possible to its exposed or visible surface (A surface), in order to provide the most efficient interactions properties with the interior of the vehicle and its occupants, while simultaneously keeping the functional part easily connectable (to an electrical power delivering source or an electrical/electronical device) when installing the trim part in its mounting site.

The invention focuses especially on trim parts comprising at least: an underlying structural support layer, a covering layer viewable on or forming the exposed face of the trim part and at least one thin surface element with at least one functional area, located between the aforementioned support and covering layers and in direct contact over its entire surface with at least the support layer.

The functional element may or may not extend over the whole surface of the support layer, and several elements may be provided, while being arranged in specific locations on said support layer. A major problem arising with respect to the previous various possibilities of layouts is that of the connection of the functional element depending on the relative positioning of the functional element in the trim part towards that of the device or source it needs to be connected to. Using possible existing holes in the trim part or the nearest lateral end edge of the trim part imposes considerable constraints to design and may lead to an excessive consumption of connection material.

To try to solve this problem, it has been proposed, for example in <CIT>, to provide for the functional surface element a connection means extending through the support layer and providing on the rear face of said support layer, opposed to the exposed face, a connecting site or area for connection with an electrical power delivering source or an electrical/electronical device.

<CIT> discloses a 3D shaped trim part according to the pre-characterising part of claim <NUM> and a process for manufacturing such a part according to the pre-characterising part of claim <NUM>.

Now, these existing solutions show several drawbacks. First, it makes use of a specific separate connection part. It also provides a connection site which is located directly on the rear side of the trim part and request an additional cable to establish the interconnection. The used connection part which crosses the support layer generates a structural and mechanical discontinuity in said layer. There is no real possibility to easily change the type of the integrated functional element, nor to integrate several elements simultaneously.

The aim of the invention is to propose a solution which overcomes at least some, preferably all, of the drawbacks exposed previously and advantageously does not noticeably alter the existing manufacturing process of the trim part made without any functional element.

In this regard, the invention concerns in a first aspect a multi-layered self-supporting 3D shaped trim part according to the pre-characterising part of claim <NUM> and showing also the features of the characterising part of claim <NUM>.

It also concerns a process for manufacturing such a part according to the pre-characterising part of claim <NUM> and showing also the features of the charracterising part of claim <NUM>.

Claims <NUM> to <NUM> and <NUM> to <NUM> are related to possible further advantageous features or alternative embodiments of the invention.

The invention will be better understood using the description below, which relates to preferred embodiments, given by way of non-limiting examples and explained with reference to the accompanying drawings, in which:.

As shown in <FIG>, <FIG>, <FIG> and <FIG> in particular, the invention concerns in a first aspect, a multi-layered self-supporting 3D shaped trim part (<NUM>) having an exposed face (<NUM>'), in particular a trim part for an automotive vehicle, such as for example an interior covering or lining part.

Said trim part (<NUM>) comprises at least one underlying structural support layer (<NUM>), at least one overlying covering layer (<NUM>, <NUM>) viewable on or forming the exposed face (<NUM>') of the trim part (<NUM>), or at least part of it, and at least one thin surface element (<NUM>) with at least one functional area (<NUM>'), located between the aforementioned support (<NUM>) and covering (<NUM>) layers and in direct contact over its entire surface with at least the support layer (<NUM>). Said at least one functional surface element (<NUM>) is associated with at least one connection means (<NUM>") extending through the support layer (<NUM>) and providing on the rear face (<NUM>') of said support layer (<NUM>), opposed to the exposed face (<NUM>'), a connecting site or area (<NUM>‴) for connection with an electrical power delivering source and/or an electrical/electronical device.

The support layer (<NUM>) consists of a thermo-compressed thermoplastic material layer reinforced with fibres.

According to the invention, said support layer (<NUM>) has been obtained by 3D shaping by thermocompression of a blank (<NUM>) of mixed polypropylene fibres and natural fibres and the or each connection means consists of an integral local extension (<NUM>") of the functional surface element (<NUM>) which crosses the support layer (<NUM>) at a throughway (<NUM>") in the original composite material blank (<NUM>) of said support layer (<NUM>), which is sealed during thermocompression.

Thanks to these specific features, i.e. the crossing of the original blank of fibrous material (corresponding to the support layer in its raw uncompressed state) by the local extension and the subsequent sealing of said throughway, said connection means can cross the support layer at any location which is most suited and convenient, in particular with respect to the location of the source or the device it will be connected to. It is thus not constraint by any limitation resulting for example from design, or local circumstances or arrangements. Furthermore, no additional element is needed to ensure the crossing through the support layer and the integrity, tightness, and mechanical resistance of said support layer are not affected due to its constitution and its thermocompression treatment. The or each throughway (<NUM>") preferably results from a single slit through the material blank (<NUM>), with no material being taken off (no piece is cut out and the go-through opening (slot) is closed during thermocompression). Moreover, the connection means are firmly hold in place in the support layer without any additional fixing means. Finally, the operational steps necessary to integrate the functional element into the trim part are easy to perform and can be smoothly incorporated into the existing production process of the trim part. And also, the one-piece design of the functional element with its connection means allows to avoid any preassembling step and renders its handling easier.

Preferably, the trim part (<NUM>) incorporates one functional surface element (<NUM>) which has one local extension (<NUM>"). But of course, several elements (<NUM>) may be present, and the or at least one of said element(s) may comprise at least two local extensions (<NUM>"), at different locations and/or connected to different parts of the considered element (<NUM>). Moreover, the or at least one element (<NUM>) may be able to perform at least two different functions. The or each functional surface element (<NUM>) extends preferably only over a part of the surface of the support layer (<NUM>), and even when several surface elements are present, they may not cover said surface.

As shown for example on <FIG>, <FIG>, <FIG>, <FIG> and <FIG>, the or each local extension (<NUM>") consists of an electrical feed line with a first portion (<NUM>) crossing the support layer (<NUM>) and embedded within it, in direct contact with its constitutive material, and with a second portion (<NUM>') extending beyond the opening of the throughway (<NUM>") on the rear face (<NUM>') of the support layer (<NUM>) and provided over at least part of its length with a connecting area (<NUM>‴) or, preferably at its free end (<NUM>"), with a connecting site (<NUM>‴), advantageously in the form of a connector. Said electrical feed line (power feed and /or electrical signals, possibly bidirectional) may comprise one or preferably at least two or more conductive wires or stripes (<NUM>).

Preferably, the electrical feed line comprises one or several individual conductive wires or ribbons for transmitting electrical power and/or signals, which are advantageously embedded in a supporting matrix and form together the local extension (<NUM>"), as illustrated in said figures.

According to the invention, and as illustrated on <FIG>, the throughway (<NUM>") corresponds to a slot, notch or cut-out opening (<NUM>') realised in the original composite material blank (<NUM>) (uncompressed fibrous blank) of said support layer (<NUM>), which is sealed during thermocompression. Furthermore, the portion (<NUM>) of the local extension (<NUM>") crossing said support layer (<NUM>) is directly contacted by and embedded in its thermocompressed constitutive material.

In order not to be noticeably affected by the thermocompression stage and also to be easily lodged thin spaces and passed through slot-like apertures, and as illustrated on <FIG> and <FIG>, it can be envisaged that at least the second portion (<NUM>') of said feed line (<NUM>") and said the associated connecting site (<NUM>‴) have a flat shape, said second portion (<NUM>') being preferably at least partly flexible and including all the wires or stripes (<NUM>). Preferably the first portion (<NUM>) is also flatly shaped (for example has a sectional shape identical to the one of the second portion), so as to be able to cross a slot like cut in the blank (<NUM>) forming the support layer after thermocompression.

According to a second embodiment, illustrated on <FIG> and <FIG>, the second portion (<NUM>') of the feed line (<NUM>") including all the conductive wires or stripes (<NUM>) comprises or forms, at least partly over its length from its free end (<NUM>"), a rigid part (<NUM>), which is preferably tapered or pointy at said free end (<NUM>").

According to a third embodiment, illustrated on <FIG> and <FIG>, the conductive wires or stripes (<NUM>) of the local extension (<NUM>") are mutually separate and consist of individualised wires or stripes (<NUM>), each of them having possibly a rigid structure (<NUM>') over at least part of its length from its free end and being preferably tapered or sharp at said free end.

In relation with said second and third embodiments, the local extension may cross the fibrous blank (<NUM>) by simple piercing without performing any cutting in said blank. Thus, the integrity of the blank, and of the subsequent support layer, is even less affected.

As illustrated on <FIG>, <FIG>, <FIG> and <FIG>, and in order to achieve a resistant and smooth incorporation, the or each functional surface element (<NUM>) is material bonded or welded with the substrate layer (<NUM>), as a result of applied heat and pressure (ie: with no use of additional adhesive substance), and is possibly at least partially embedded within the thickness of said layer (<NUM>), preferably in a substantially flush mounted way (ie: totally surface embedded, generating no local excess thickness).

According to a first aspect of the invention, shown as two different embodiments on <FIG>, <FIG> and <FIG>, the trim part (<NUM>) may comprise a specific covering layer (<NUM>) which constitutes the top decorative and/or protective layer of the trim part (<NUM>) and is viewable on, or forms at least part of, the exposed face (<NUM>') of said trim part (<NUM>). Said top layer (<NUM>) can be either a protective coating, such as a paint or a transparent or translucid varnish, possibly incorporating additional decorative elements, such as for example pigments, particles or similar, or a material decorative layer selected from the group comprising textile fabrics, nonwoven fleeces, PVC skins, TPO skins, PP films, leather skins and cork, wood or stone veneers.

As illustrated in the <FIG> by means of four constructive variants, a comfort layer (<NUM>) consisting of a foam layer may be present on the back or rear side of the material decorative layer (<NUM>), opposed to the exposed face (<NUM>') of said trim part (<NUM>). Said comfort layer (<NUM>) is preferably a layer which is preassembled with the decorative layer (<NUM>) in the form of a laminated layer.

According to a second aspect of the invention, shown by way of two different embodiments on <FIG> and <FIG>, the trim part (<NUM>) may comprise at least two covering layers, namely a top covering layer (<NUM>) forming an exposed decorative and/or protective layer of said trim part (<NUM>) and at least one intermediary layer (<NUM>) which is located between the support layer (<NUM>) and said top covering layer (<NUM>) and which is covering at least the functional area(s) (<NUM>') of the at least one surface element (<NUM>) while shielding it from the decorative layer (<NUM>).

The top covering layer (<NUM>) may be in direct contact with the intermediary layer (<NUM>), as shown on <FIG> or indirectly through its rear side comfort layer (<NUM>), as shown on <FIG>.

Said at least one additional intermediary layer (<NUM>) is also in direct contact and joined with the functional area(s) (<NUM>') of the at least one surface element (<NUM>) and with the support layer (<NUM>), outside or beyond said functional area(s) (<NUM>') of said at least one surface element (<NUM>), and covers also at least the area of the throughway (<NUM>"), preferably the whole support layer (<NUM>).

The decorative layer (<NUM>), possibly associated with a comfort layer (<NUM>) on its rear or back side, covers at least partially, preferably substantially entirely, the support layer (<NUM>), and in any case either the functional area(s) (<NUM>') of the at least one surface element (<NUM>) or an additional intermediary layer (<NUM>), depending on the presence or not of such a layer (<NUM>).

It can be envisaged that said layers (<NUM>, <NUM>, <NUM>, <NUM>) have all similar surface extensions, that the support layer (<NUM>) has a greater surface extension than the other layer(s) or that the support layer (<NUM>) and possibly the intermediary layer (<NUM>) have greater surface extensions than the decorative layer (<NUM>).

When the decorative layer (<NUM>) only extends partly over the trim part (<NUM>), then said additional intermediary layer (<NUM>) may be extending beyond said decorative layer and thus contribute to the visual aspect of the exposed face (<NUM>'), as shown in <FIG>). Alternatively, the surface extension of said additional intermediary layer (<NUM>) may be adjusted to said partial extension (see <FIG> and <FIG>-the layer <NUM> or <NUM> arranged underneath said additional intermediary layer does then contribute to the visual aspect of the trim part (<NUM>).

When the intermediate layer (<NUM>) (<FIG>) and/or the comfort layer (<NUM>) (<FIG>) extend only over a part of the surface of the support layer (<NUM>), while always totally covering the functional part(s) (<NUM>), the peripheral edge of said layers (<NUM>, <NUM>) form a protruding shoulder, preferably covered by the decorative layer (<NUM>).

When said decorative layer (<NUM>) covers only partly the intermediate or support layer (<NUM>, <NUM>) it may also be a protruding area (i.e. form a peripheral shoulder) (<FIG>) or be arranged relatively flush with the underneath layer (<NUM> or <NUM>) (see <FIG>).

As illustrated on <FIG>, and in line with another embodiment of the invention, the exposed face (<NUM>') of the trim part (<NUM>) is partly or totally formed by an additional layer (<NUM>) which constitutes the top covering layer, a complementary part of the exposed face (<NUM>') being possibly formed by the substrate layer (<NUM>). Thus, said additional layer (<NUM>) covers at least and is in direct contact and joined with the functional area(s) (<NUM>') of the at least one surface element (<NUM>) and with the support layer (<NUM>), outside or beyond said functional area(s) (<NUM>') of the at least one surface element (<NUM>), and covers also the area of the throughway (<NUM>"), preferably the whole support layer (<NUM>).

According to a possible advantageous feature of the invention, the intermediary or additional layer (<NUM>) also consists of a thermo-compressed thermoplastic material layer, possibly reinforced with fibres, and is material bonded or welded with the substrate layer (<NUM>), as result of applied heat and pressure, its constitutive thermoplastic material being at least compatible, if not identical, with the thermoplastic material of said support layer (<NUM>).

Thus, the functional surface element (<NUM>) is encased in a shell of thermo-compressed thermoplastic material. Both layers (<NUM> and <NUM>) may be totally identical, or alternatively the layer (<NUM>) may have at least slightly different properties or a different constitution (smaller thickness, lower density, added substances,. ) depending on the specific functions it must fulfil. For example, layer (<NUM>) may be thinner and have better heat diffusion properties than layer (<NUM>), so that if the functional surface element (<NUM>) is a heating element, the heat is transmitted mainly towards the exposed surface (<NUM>').

In relation to another aspect of the invention, the decorative covering layer (<NUM>) is assembled with the support layer (<NUM>) and the functional area(s) (<NUM>') of the thin surface element (<NUM>) or with an additional intermediary layer (<NUM>), either directly as a pressure applied or overmolded layer, or by means of an adhesive or a glue. As shown on <FIG>, <FIG>, <FIG> and <FIG>, the trim part (<NUM>) may comprise one additional intermediary layer (<NUM> or <NUM>), two additional intermediary layers (<NUM> and <NUM>) or none.

As it appears on <FIG>, <FIG>, <FIG>, <FIG>, <FIG> and <FIG>, and advantageously whichever embodiment or layout of the trim part (<NUM>) of the invention is considered, the functional area(s) (<NUM>') of the thin surface element (<NUM>) is(are) always covered completely and continuously on both sides with at least one layer (<NUM>, <NUM>, <NUM>, <NUM>), and thus preferably totally encapsulated between said layers at the end of the process, but without being totally embedded within one of said layers (said thin element rests on the surfaces of said layers).

To allow an easy handling and processing of the thin functional surface element (<NUM>), as well as a good bonding with at least the support layer (<NUM>), and as shown on <FIG>, <FIG> and <FIG>, the or each thin functional surface element (<NUM>) is assembled with or incorporated within a supporting matrix or layer (<NUM>) compatible with the material of the support layer (<NUM>). Said element is preferably designed to perform at least one of the functions selected in the group comprising: heating, illuminating, displaying images, graphics and/or text, pressure or contact sensing, sensing at least one physical parameter of its environment, receiving and/or emitting electromagnetic waves. According to a possible practical aspect of the invention, the functional surface element (<NUM>) comprises a thermoplastic or textile supporting matrix (<NUM>) bearing or incorporating at least one electronic or electric component (<NUM>') designed to perform the expected function of said functional element (<NUM>), and preferably also the conductive wires or stripes (<NUM>) of the local extension (<NUM>').

In relation to a favourable embodiment of the invention, the material of the support layer (<NUM>) is composed of a polypropylene matrix (PP) incorporating natural fibres (NF) as reinforcing fibres with a weight percentage PP/NF comprised between <NUM>%/<NUM>% and <NUM>%/<NUM>%, preferably between <NUM>%/<NUM>% and <NUM>%/<NUM>%, and said support layer (<NUM>) shows a surface weight between <NUM>/m<NUM> and <NUM>/m<NUM>, preferably between <NUM>/m<NUM> and <NUM>/m<NUM> and a thickness between <NUM>,<NUM> and <NUM>,<NUM>, preferably between <NUM>,<NUM> and <NUM>,<NUM>.

According to a first constructive aspect, the material of the covering layer (<NUM>) forming an additional intermediary layer is composed of a polypropylene matrix (PP) incorporating natural fibres (NF) with a weight percentage PP/NF comprised between <NUM>%/<NUM>% and <NUM>%/<NUM>%, preferably between <NUM>%/<NUM>% and <NUM>%/<NUM>%, and said covering layer (<NUM>) shows a surface weight between <NUM>/m<NUM> and <NUM>/m<NUM>, preferably between <NUM>/m<NUM> and <NUM>/m<NUM> and a thickness between <NUM>,<NUM> and <NUM>,<NUM>, preferably between <NUM>,<NUM> and <NUM>,<NUM>.

According to a second constructive aspect, the covering layer (<NUM>) forming an additional intermediary layer is entirely made of polypropylene (PP) or polyethylene (PE), polyethylene terephthalate (PET) or PET bicomponent coextruded, and said covering layer (<NUM>) shows a surface weight between <NUM>/m<NUM> and <NUM>/m<NUM>, preferably between <NUM>/m<NUM> and <NUM>/m<NUM> and a thickness between <NUM>,<NUM> and <NUM>,<NUM>, preferably between <NUM>,<NUM> and <NUM>,<NUM>.

Preferably, the reinforcing fibres are natural fibres, such as for example flax, sisal, jute, hemp or kenaf fibres, thermoplastic fibres, glass fibres, carbon fibres or mixtures of at least two different types of such fibres.

The invention also encompasses, as illustrated on <FIG> and <FIG>, a process for manufacturing a multi-layered self-supporting 3D shaped trim part (<NUM>) as described before, and comprising at least one thin functional surface element (<NUM>).

According to the invention, said process is characterised in that it consists mainly in:.

It should be noted that the process illustrated on <FIG> results in a trim part (<NUM>) having only a decorative layer (<NUM>), whereas the process illustrated in <FIG> (NB: the thermo-compressing stages are not shown on these figures) results in a trim part (<NUM>) having a decorative layer (<NUM>) and an intermediary layer (<NUM>).

More precisely, and according to a first embodiment of the invention, the manufacturing method may comprise the following successive operational steps:.

The opening (<NUM>') which will form the throughway (<NUM>") in the trim part (<NUM>) results preferably from a single slit or cut through the material blank (<NUM>), with no material being cut off (no piece is cut out and the go-through opening (slot) is closed during thermocompression). Said slit or slot is advantageously realised by using a cold blade, for example mounted onto and manipulated by a robotic arm.

Preferably, and as shown on <FIG>, <FIG> and <FIG>, realising the opening (<NUM>') consists in realising a through U-shaped cut (<NUM>') in the blank (<NUM>), when seen in the median plane of said blank, so as to provide a bendable tong (<NUM>) of mat or fleece material, the local extension (<NUM>") being preferably a flat cable or wire.

In relation to a second embodiment, and as illustrated on <FIG> and <FIG>, step ii) comprises providing a surface element (<NUM>) with a second portion (<NUM>') of the local extension (<NUM>") including all the conductive wires or stripes (<NUM>) and forming, at least partly over its length from its free end (<NUM>"), a rigid part (<NUM>), which is preferably tapered or pointy at said free end (<NUM>"), like a needle, and pushing said rigid (<NUM>) part through the blank (<NUM>) of mixed polypropylene fibres and natural fibres, so as to locate the second portion (<NUM>') on the other side of it.

In relation to a third embodiment, and as illustrated in <FIG> and <FIG>, step ii) comprises providing a surface element (<NUM>) wherein the wires or stripes (<NUM>) of the local extension (<NUM>") are mutually separate and consist of individualised wires or stripes (<NUM>), each of them having possibly a rigid structure (<NUM>') over at least part of its length from its free end and being preferably tapered or sharp at said free end, like needles, and pushing said rigid structures (<NUM>') through the blank (<NUM>) of mixed polypropylene fibres and natural fibres, so as to locate the second portion (<NUM>') of the local extension (<NUM>") on the other side of it.

In relation to a fourth embodiment of the invention, step ii) comprises providing a surface element (<NUM>) wherein the wires or stripes (<NUM>) of the local extension (<NUM>") are mutually separate and consist of individualised wires or stripes (<NUM>), introducing said wires or stripes (<NUM>) into a hollow guiding element (<NUM>'), preferably tapered, such as a hollow needle, and pushing said guiding element (<NUM>') through the blank (<NUM>) of mixed polypropylene fibres and natural fibres, so as to locate the parts of the wires or stripes forming the second portion (<NUM>') of the local extension (<NUM>") on the other side of it, and then extracting said wires or stripes (<NUM>) from said guiding element (<NUM>') and removing the latter.

These second to fourth embodiments in relation to step ii) may be considered as alternatives or more detailed processes of step d) of the previous first embodiment.

The fin functional element (<NUM>) may comprise a support layer made of textile (nonwoven, fleece, woven, knitted), film, skin, plastic layer, metallic layer or similar. To fulfil the requested function(s) electric yarns can be integrated, or laid on the previous support; also electric conductor activatable ink can be laid on the support. All these conductive components or materials have a specific design to make the power flow all around, or to give the specific functional effect. The functional component may also be an electroluminescent film to transmit light.

Depending on its nature and functionality, the at least one thin surface element (<NUM>) with at least one functional area (<NUM>'), which has generally a thickness of less than <NUM>, may advantageously present a thickness comprised between <NUM>,<NUM> and <NUM>,<NUM>, preferably between <NUM>,<NUM> and <NUM>,<NUM>.

As shown on <FIG>, and before the thermocompression step, a protection element (<NUM>) is advantageously arranged on the rear side (<NUM>') of the blank (<NUM>), where the second portion (<NUM>') of the local extension (<NUM>") emerges from the blank (<NUM>), said protection element (<NUM>) forming a shielding layer between the local extension (<NUM>") of the surface element (<NUM>) and said rear side (<NUM>') and facilitating the separation of the protruding portion (<NUM>') of the local extension (<NUM>") and of the connecting site or area (<NUM>‴), from said rear face (<NUM>').

As illustrated on <FIG> for example, and in order to achieve a decorative layer (<NUM>) or an additional intermediary covering layer (<NUM>), the process may also consist in providing another blank (<NUM>) of material made of a mixture of polypropylene fibres and natural fibres, made of polypropylene fibres or made of polyethylene fibres and arranging said second blank (<NUM>) on the first blank (<NUM>) equipped with said surface element (<NUM>) after step ii) or after step d) mentioned previously, and then shaping together by thermo-compression said two associated blanks (<NUM>, <NUM>) and said element (<NUM>) so as to produce a blank part in the shape of the intended trim part (<NUM>) and incorporating the support layer (<NUM>), the surface element (<NUM>) and an additional layer (<NUM>) corresponding to said thermo-compressed other blank (<NUM>) and covering at least the surface element (<NUM>) (if an additional decorative covering layer is added on top of it). As illustrated in the <FIG>, the inventive manufacturing process may also comprise applying a top covering layer (<NUM>) which extends over a part of or the whole support layer (<NUM>), and covers at least the functional area(s) (<NUM>') of the at least one surface element (<NUM>), said top covering layer (<NUM>) consisting either in a protective coating, such as a paint or a transparent or translucid varnish, possibly incorporating additional decorative elements, such as for example pigments, particles or similar, or in a material decorative layer selected from the group comprising textile fabrics, nonwoven fleeces, PVC skins, TPO skins, PP films, leather skins and cork, wood or stone veneers. The inventive manufacturing process may also provide that a comfort layer (<NUM>) consisting of a foam layer is present on the back or rear side of the material decorative layer (<NUM>), opposed to the exposed face (<NUM>') of said trim part (<NUM>).

In order to achieve an accurate mounting, the arrangement of the thin functional surface element (<NUM>) on the blank (<NUM>) intended to form the support layer (<NUM>) may be guided and maintained, preferably locked in position, by means of indexing elements when placed in the thermoforming mould (<NUM>).

Claim 1:
A multi-layered self-supporting 3D shaped trim part (<NUM>) having an exposed face (<NUM>'), in particular a trim part for an automotive vehicle, such as for example an interior covering or lining part, said trim part (<NUM>) comprising at least one underlying structural support layer (<NUM>), at least one overlying covering layer (<NUM>, <NUM>) viewable on or forming the exposed face (<NUM>') of the trim part (<NUM>), or at least part of it, and at least one thin surface element (<NUM>) with at least one functional area (<NUM>'), located between the aforementioned support (<NUM>) and covering (<NUM>, <NUM>) layers and in direct contact over its entire surface with at least the support layer (<NUM>), wherein said support layer (<NUM>) consists of a thermo-compressed thermoplastic material layer reinforced with fibres, said at least one functional surface element (<NUM>) being associated with at least one connection means (<NUM>") extending through the support layer (<NUM>) and providing on the rear face (<NUM>') of said support layer (<NUM>), opposed to the exposed face (<NUM>'), a connecting site or area (<NUM>‴) for connection with an electrical power delivering source and/or an electrical/electronical device,
said trim part (<NUM>) being characterized in that said support layer (<NUM>) has been obtained by 3D shaping by thermocompression of a blank (<NUM>) of mixed polypropylene fibres and natural fibres, in that the or each connection means consists of an integral local extension (<NUM>") of the functional surface element (<NUM>) which crosses the support layer (<NUM>) at a throughway (<NUM>") in the original uncompressed composite material blank (<NUM>) of said support layer (<NUM>), corresponding to a slot, notch or cut-out opening (<NUM>') realised in the original composite material blank (<NUM>) of said support layer (<NUM>), which is sealed during thermocompression, and in that the portion (<NUM>) of the local extension (<NUM>") crossing said support layer (<NUM>) is directly contacted by and embedded in its thermocompressed constitutive material.