Patent Description:
In a number of motor vehicles, a door assembly is designed such that there is a first, e.g., forward, window opening that carries a movable window pane and a second, e.g., rearward, opening that is equipped with a fixed or stationary window pane. Of course, the forward window pane may be fixed and the rearward window pane may be moveable. Fixed windows of conventional design may be assembled from discrete elements that include the window panel, a post that serves as a track for an adjacent movable window and various configurations of moldings or trim pieces or division posts, most specifically an extruded header/B-pillar trim piece that may be mechanically attached to the window module assembly using an interlocking channel or the like.

The division post in some prior art designs comprises an article in the nature of a pre-formed resilient band. In those designs, the window is inserted into a channel of the trim band which resiliently engages the window pane, but often less than securely. Conventional designs suffer from a number of deficiencies due to their assembly from discrete components such as water leakage, noise from the exterior (wind noise) or the interior, and problems generally with fit and finish. In addition, the assembly of these modules is often difficult, particularly where the individual components are manufactured by more than one supplier.

A few of the problems of conventional designs are overcome through the use of over-molding processes by which a portion of the trim or post surrounding the window pane is fabricated by encapsulating the window periphery with a polymer using injection molding techniques. In essence, the window pane is placed in a mold cavity which is configured to produce a circumferential trim at the pane edges. A division post profile and a header profile are also placed in the mold cavity. In some case, an additional margin seal extrusion can be added to the mold cavity. The edges of the pane on which the injection molded trim will adhere are cleaned and primed to promote adhesion and to create a water-impervious seal in the formed article. The mold is then closed and the material is injected such that the window pane edges are encapsulated to form the desired trim geometry.

<FIG> is a cross sectional view of adjacent window panes <NUM>, <NUM> of a motor vehicle. The window pane <NUM> is fixed and the window pane <NUM> is movable. The fixed window pane <NUM> has an exterior surface 1a, an interior surface 1b, and a peripheral edge 1c extending between said exterior and interior surfaces 1a, 1b. A division post <NUM> extends along the peripheral edge 1c and is secured thereto by an over-molded material <NUM>.

The division post <NUM> is U-shaped in cross section and has an exterior wall 3a, an interior wall 3b, and a lateral wall 3c connecting said exterior and interior walls 3a, 3b. The division post <NUM> defines a longitudinal groove <NUM> configured to receive a portion of the movable window pane <NUM>. The lateral wall 3c of the division post <NUM> is in abutment against the peripheral edge 1c of the fixed window pane <NUM> and said over-molded material <NUM> comprises a first portion 4a extending between the lateral wall 3c and the exterior surface 1a, and a second portion 4b extending between the lateral wall 3c and the interior surface 1b.

This configuration creates a small offset O between the interior surface 1b and the interior wall 3b and requires limited amount of over-molded material on both sides of the fixed window pane <NUM>. The risk of appearance issue due to sink marks is therefore low.

The exterior appearance of the window modules is very important for the customer, i.e., the user of the motor vehicle. A solution for enhancing the appearance of a window module is to provide the periphery of the window pane with finished panels which are located outside the motor vehicle and are visible by the user. Said finished panels are for instance esthetic metal components which are secured to the window module.

It is also known to enhance the esthetic appearance of a window module by lying flush the outside of its stationary window pane with the outside of an adjacent movable window pane.

<FIG> is a cross sectional view of adjacent and flush window panes <NUM>, <NUM> of a motor vehicle. The division post <NUM> extends along the peripheral edge 1c and is secured to the interior surface 1b by an over-molded material <NUM>.

The division post <NUM> defines a longitudinal groove <NUM> configured to receive a guiding mean <NUM> carried by the movable window pane <NUM>. The exterior wall 3a of the division post <NUM> faces the interior surface 1b and is secured thereto by the over-molded material <NUM>.

The over-molded material <NUM> comprises a first portion 4a extending between the exterior wall 3a and the interior surface 1b and a second portion 4b extending between the lateral wall 3c and the interior surface 1b. <FIG> shows that the first portion 4a has a thickness E1 which is constant (the thickness, E1 being measured in a direction D1 perpendicular to the interior surface 1b and/or to the exterior wall 3a). On the contrary, the second portion 4b has a bigger thickness E2 which is not constant and which varies (the thickness, E2 is measured in a direction D2 perpendicular to the lateral wall 3c). The thickness E2 of the second portion 4b is higher in the proximity of the interior surface 1b than on the opposite end in the proximity of the interior wall 3b.

The over-molded material <NUM> comprises an outer face 4c which extends between the lateral wall 3c and the interior surface 1b and which includes a major portion 4c1 which is inclined with respect to the interior surface 1b. Due to feasibility reasons, it is not possible to get a major portion 4c1 perpendicular to the interior surface 1b during the over-molding process.

In this flush configuration, a large offset O is created between the interior surface 1b and the interior wall 3b and a large amount of over-molded material <NUM> is needed to fill this offset O. The risk of appearance issue due to sink marks is therefore high. Indeed, after de-molding, the over-molded material <NUM> cools and hardens. The large amount of over-molded material promotes the formation of sink marks and surface defects on the outer face 4c. Since this outer face 4c may be visible to the user of the motor vehicle, these sink marks and surface defects are problematic. An example of such a configuration is shown in <CIT>.

The present invention provides at least an encapsulated fixed window module which can be used in a flush configuration and which avoids the above-mentioned appearance issue of the over-molded material.

According to the invention there is provided an encapsulated fixed window module for a motor vehicle, comprising:.

In the present specification, the words "inner", "inside", "interior", etc., make reference to the inside of a motor vehicle. The words "outer" "outside", "exterior", etc., make reference to the outside of the motor vehicle. Then, an outer element is located at the outer side of the vehicle. A first outer element, portion or surface may be visible by a user of the motor vehicle or may be hidden by a second outer element, portion or surface covering said first outer element.

In the present specification, "aligned" and "substantially aligned" mean that two elements are strictly aligned or are aligned in a range <NUM> to <NUM>, preferably <NUM> to <NUM> and more preferably <NUM> to <NUM>.

The present invention provides a solution for enhancing the esthetic appearance of a fixed window module. This aim is achieved by keeping the thickness of the over-molded material as constant as possible. The second portion of the over-molded material is constant along a major portion of this second portion along a direction perpendicular to the interior surface of the fixed window pane. The thicknesses of the first and second portions of the over-molded material may be similar. Having a consistent thickness allows all the molded areas to cool at the same speed and prevent "sink-marks" and other appearance defects.

The encapsulated fixed window module according to the invention may comprise one or more of the following features, taken alone from each other or in combination with each other:.

The invention further proposes a motor vehicle, comprising at least one encapsulated fixed window module as defined above.

The motor vehicle may comprise a door including a door frame, a movable window pane, and said encapsulated fixed window module, said movable window pane having an exterior surface, an interior surface, and a peripheral edge extending between said exterior and interior surfaces, wherein said exterior surfaces of said encapsulated fixed window module and of said movable window pane are substantially coplanar.

The invention will be better understood and other details, features and advantages of the invention will appear more clearly on reading the following description given by way of non-limiting examples and with reference to the accompanying drawings in which:.

<FIG> have been already described and illustrate the prior art.

<FIG> shows an example of an encapsulated fixed window module <NUM> for a motor vehicle.

A motor vehicle door comprises a door frame provided with an encapsulated fixed window module <NUM> which can be adjacent to a movable window pane <NUM>. In the example of <FIG>, a rear door of a vehicle is shown in which case the pane <NUM> is a forward pane and the module <NUM> is a rearward module. Another configuration would be on a front door, with in that case the movable window pane <NUM> positioned rearwardly from the module <NUM>.

The module <NUM> includes at least a fixed window pane <NUM> molded on up to four extremities or along four edges. The or each molding forms an encapsulation <NUM>.

Each pane <NUM>, <NUM> has an exterior surface 12a, 14a intended to be located outside the motor vehicle, an interior surface 12b, 14b intended to be located inside the motor vehicle, and a peripheral edge 12c, 14c extending between said exterior and interior surfaces (see <FIG> and <FIG>).

Each pane <NUM>, <NUM> may be substantially flat. Thus, its surfaces 12a, 14a, 12b, 14b may be substantially flat. Of course, the pane <NUM>, <NUM> and its surfaces may be slightly curved according to the expected design of the module. As shown in <FIG>, the peripheral edge 12c, 14c may have a cross sectional convex shape.

In the example shown, each pane <NUM>, <NUM> has a polygonal shape and comprises four longitudinal edges. Each peripheral edge 12c, 14c includes therefore a top edge 12ca, 14ca, a front edge 12cb, 14cb, a bottom edge 12cc, 14cc and a rear edge 12cd, 14cd (see <FIG>).

The door may further comprise an appliqué <NUM>, the movable window pane <NUM> being located between the stationary window pane <NUM> and the appliqué <NUM>. The exterior surface 12a of the pane <NUM> is advantageously flush with the exterior surface 14a of the pane 14a and the exterior surface 13a of the appliqué <NUM>.

<FIG> is a cross sectional view at the top edge 12ca of the movable window pane. <FIG> is a cross sectional view at the top edge 14ca of the fixed window pane. <FIG> is a cross sectional view at the rear edge 14cd of the fixed window pane. <FIG> is a cross sectional view at the front edge 14cb of the fixed window pane and at the rear edge 12cd of the movable window pane <NUM>.

These figures show that the encapsulation <NUM> extends along the edges 14ca, 14cb and 14cd of the pane <NUM>. Glass edge 14ca and the inboard side of the glass next to 14cb are encapsulated. Encapsulation of glass edges 14cd and 14cc is optional.

Thus, the encapsulation <NUM> extends along at least two edges of the pane <NUM> in the example shown but may not necessarily cover these edges as will be detailed below. The encapsulation <NUM> may comprise segments or profiles or division posts each extending along a portion of the longitudinal edges of the pane <NUM>. Each profile of the division post has a length and a width, its length being greater than its width and extending along said portion of the longitudinal edges of the pane <NUM>.

<FIG> shows a longitudinal profile which is called "third" profile <NUM>. This third profile <NUM> extends along said edges 14ca and 12ca. The portion of the profile <NUM> shown in <FIG> is the one extending along the edge 12ca and is not over-molded.

A substantially vertical profile (not shown) is molded to profile <NUM> to be part of module <NUM>, in order to guide the moveable glass edge 12cb.

The third profile <NUM> shown in <FIG> has first and second U-shaped portions 18a, 18b in cross section.

The first U-shaped portion 18a defines a longitudinal groove <NUM> that is oriented inwardly and is configured to receive a metallic flange <NUM> of the motor vehicle. In the example shown, the metallic flange includes two substantially horizontal panels that are superimposed and inserted into the groove <NUM>. The first portion 18a includes an exterior wall 18aa connecting two lateral walls 18ab, 18ac defining the groove <NUM> therebetween.

The second U-shaped portion 18b defines a longitudinal groove <NUM> that is oriented downwardly in a plane parallel to the panes <NUM>, <NUM> and which is configured to receive by sliding an upper portion of the movable window pane <NUM>. The second portion 18b includes an interior wall 18ba and an exterior wall 18bb connected by a lateral wall which may be integrated in said lateral wall 18ac as shown in the figure. The walls of the second portion 18b define said groove <NUM>.

Both portions 18a, 18b include sealing lips intended to cooperate with the pane <NUM> and/or parts of the vehicle.

The third profile <NUM> further may include an elongated esthetic component <NUM> which extends along the profile <NUM> and is secured onto both portions 18a, 18b. The component <NUM> includes an esthetic exterior face 30a and an interior face 30b. The component <NUM> includes a substantially flat portion including the faces 30a, 30b and longitudinal hooks 30c extending inwardly from the inner face 30b. The hooks 30c are used to mechanically secure the component <NUM> onto the profile <NUM>. The component <NUM> is intended to cover at least portions of said exterior walls 18aa, 18bb which both comprise grooves intended to receive the hooks 30c by snap fitting.

<FIG> still shows the third profile <NUM> and in particular its portion extending along the edge 14ca and is over-molded.

This portion of the profile <NUM> differs from the portion of <FIG> in that it does not comprise the interior wall 18ba and in that it is secured to the fixed window pane <NUM> by an over-molded material <NUM>.

This over-molded material <NUM> extends onto the inner surface of the exterior wall 18bb, the downward surface of the lateral wall 18ac and also over the edge 14ca and portions of the surfaces 14a, 14b of the fixed window pane <NUM>. This over-molded material <NUM> may have lips or legs intended to abut against parts of the vehicle.

<FIG> shows a longitudinal profile which is called "second" profile <NUM>. This second profile <NUM> extends along said edge 14cd and is over-molded.

The second profile <NUM> shown in <FIG> is U-shaped in cross section and defines a longitudinal groove <NUM> that is oriented inwardly and is configured to receive a metallic flange <NUM> of the motor vehicle. In the example shown, the metallic flange <NUM> includes two substantially vertical panels that are superimposed and inserted into the groove <NUM>.

The second profile <NUM> includes an exterior wall 20a and two lateral walls 20b, 20c connected by said exterior wall 20a. The exterior wall 20a is usually parallel to the interior surface 14b of the fixed window pane <NUM> and is secured thereto by an over-molded material <NUM>. In the example shown, the exterior wall 20a faces the interior surface 14b and spaced therefrom. This space S is filled in with said over-molded material <NUM>.

The lateral wall 20b is substantially aligned with a portion (the rear edge 14cd in the example shown) of said peripheral edge 14c in a plane P1 that is perpendicular to the fixed window pane <NUM>. The lateral wall 20c extends perpendicularly to and faces the interior surface 14b.

In the example shown, the over-molded material <NUM> further extends over the lateral wall 20c and the frond edge 14cd. The lateral wall 20b is free of such over-molded material <NUM>. Said over-molded material <NUM> is V-shaped (with an angle lower than <NUM>°) in front of the rear edge 14cd and defines a first planar surface 36a aligned with the exterior surface 14a and a second planar surface 36b which extends between the first surface 36a and the profile <NUM> and is inclined with respect to said plane P1.

The second profile <NUM> includes sealing or retention lips intended to cooperate with parts of the vehicle.

<FIG> shows another longitudinal profile which is called "first" profile <NUM>, also known as division post. This first profile <NUM> extends substantially vertically along said edges 12cd, 14cb and is over-molded.

The first profile <NUM> shown in <FIG> is U-shaped in cross section and defines a longitudinal groove <NUM> that is oriented forwardly and is configured to receive a guiding mean <NUM> secured to the movable window pane <NUM>.

The first profile <NUM> includes an exterior wall 22a and an interior wall 22b connected together by a lateral wall 22c and defining the groove therebetween. The exterior wall 22a is parallel to the interior surface 14b of the fixed window pane <NUM> and is secured thereto by an over-molded material <NUM>. In the example shown, the exterior wall 22a faces the interior surface 14b and is L-shaped in cross section. The exterior wall 22a includes first and second parts 22aa, 22ab that are perpendicular to one another, said first part 22aa being spaced from the interior surface 14b and extending between said lateral wall 22c and said second part 22ab. Said second part 22ab is applied directly onto said interior surface 14b. Said first part 22ab defines a space S with said interior surface 14b that is filled in with the over-molded material <NUM>.

The over-molded material <NUM> further extends over at least a portion of said lateral wall 22c. The over-molded material <NUM> does not cover the peripheral edge 14cb along said first profile <NUM>, i.e., the front edge 14cb, in the example shown.

The exterior wall 22a has a longitudinal edge 22a1 which is opposite to the lateral wall 22c that is substantially aligned with said front edge 14cb in a plane P2 that is perpendicular to the fixed window pane <NUM>.

This longitudinal edge 22a1 carries a first sealing lip <NUM> which is configured to abut against both edges 14cb and 12cd. The sealing lip <NUM> is the sole member extending between said edges 14cb and 12cd. The sealing lip <NUM> is curved (concave or convex) and defines a groove oriented inwardly. The lip <NUM> includes a longitudinal connecting edge 44a which extends in the plane P2 and is secured to the longitudinal edge 22a1, and further includes an opposite longitudinal sealing edge 44b abutting against the rear edge 12cd of the pane <NUM>. The longitudinal portion of the sealing lip <NUM> extending between both edges 44a, 44b has an exterior surface 44c which is substantially aligned with said exterior surfaces 14a, 12a.

As far as the interior wall 22b of the first profile <NUM> is concerned, it crosses said plane P2 and is configured to face said guiding mean <NUM>, and preferably also to face the interior surface 12b of the movable window pane <NUM> as shown in the figure.

The interior wall 22b carries a second sealing lip <NUM> which is configured to be in sealing contact with the guiding mean <NUM>. In another example, only the first and the third sealing lips may be provided (no sealing is then provided on the guiding mean <NUM>).

The guiding mean <NUM> may be formed of a single longitudinal part that is secured, for instance by gluing or over-molding, onto the interior surface 12b of the pane <NUM> and includes a guiding leg 40a crossing the plane P2 and received into the groove <NUM> for sliding motion. As shown in the drawings, the surfaces of the groove <NUM> may be coated with an antifriction layer suitable to cooperate by sliding with the guiding mean <NUM> and in particular its leg 40a. Therefore, as shown in the drawings, the walls 22a, 22b, 22c may be coated with the antifriction layer inside the groove <NUM>.

As shown in <FIG>, each profile <NUM>, <NUM>, <NUM> may comprise at least one U-shaped metallic rail embedded or encapsulated into a polymeric covering. The rail includes an interior branch and an exterior branch, connected together by a lateral branch. Each profile and its polymeric covering may be made by co-extrusion. The sealing lips may be made of an elastically deformable material, such as for example EPDM or thermoplastic. These lips may be obtained by over-molding during a process where the profiles <NUM>, <NUM>, <NUM> are connected together in their interconnection zones. Of course, each profile might not comprise metallic rail and might therefore comprise only polymeric materials. Each profile may have polypropylene in areas where material rigidity is needed and the lips might be made of a softer material. The profiles are secured onto the fixed window pane <NUM> by over-molding by means of the over-molded material <NUM>, <NUM> and <NUM>. Stationary glass edge 14cc is usually encapsulated as well.

<FIG> is a view similar to the view of <FIG> and <FIG> and shows a first embodiment according to the invention.

The invention relates to an encapsulated fixed window module which is similar to the encapsulated window module described above in relation with <FIG>. The above description made in reference to <FIG> applies therefore to the claimed invention and the description of <FIG> of the former embodiment may be replaced by the following description of <FIG> which illustrates the first embodiment of the invention.

The reference numerals used in relation to <FIG> are used for designating the same elements in <FIG>.

The window panes <NUM> and <NUM> are similar to the ones disclosed above. The guiding mean <NUM> is also similar.

The (first) profile <NUM> or division post of <FIG> extends along the edges 12cd, 14cb and is over-molded.

The profile <NUM> shown in <FIG> is U-shaped in cross section and defines a longitudinal groove <NUM> that is oriented forwardly and is configured to receive the guiding mean <NUM> secured to the movable window pane <NUM>.

The profile <NUM> includes an exterior wall 22a and an interior wall 22b connected together by a lateral wall 22c and defining the groove <NUM> therebetween. The exterior wall 22a is parallel to the interior surface 14b of the fixed window pane <NUM> and is secured thereto by an over-molded material <NUM>.

As shown in the drawings, the surfaces of the groove <NUM> may be coated with an antifriction layer F1 suitable to cooperate by sliding with the guiding mean <NUM> and in particular its leg 40a. Therefore, as shown in the drawings, the walls 22a, 22b, 22c may be coated with the antifriction layer F1 inside the groove <NUM>.

The exterior wall 22a has a surface 22a1 that faces the interior surface 14b and is L-shaped in cross section. The exterior wall 22a includes first and second parts 22aa, 22ab that are perpendicular one another, said first part 22aa being spaced from the interior surface 14b and extending between said lateral wall 22c and said second part 22ab. Said second part 22ab is applied directly onto said interior surface 14b in the vicinity of the edge 14c, 14cb.

Said second part 22ab carries a protruding leg <NUM> which extends externally in a direction substantially perpendicular to the exterior wall 22a. The protruding leg <NUM> is interposed in the gap between both peripheral edges 12cb, 14cb, and is in abutment against the peripheral edge 14cb. The protruding leg <NUM> carries a first sealing lip <NUM> which is configured to abut against the edge 12cb. The first sealing lip <NUM> has an exterior surface 44c which is substantially aligned with the exterior surfaces 14a, 12a.

The protruding leg <NUM> is made of the same material as the main material (or polymeric covering) of the profile <NUM>. The first sealing lip <NUM> is preferably made of a softer material.

The exterior wall 22a, and in particular its first part 22aa, defines a space S with the interior surface 14b that is filled in with the over-molded material <NUM> and in particular with a first portion 142a of this over-molded material <NUM>.

The over-molded material <NUM> further extends over at least a portion of said lateral wall 22c and comprises a second portion 142b extending between the lateral wall 22c and the interior surface 14b. The over-molded material <NUM> does not cover the peripheral edge 14cb in the example shown.

As far as the interior wall 22b of the first profile <NUM> is concerned, it is longer than the exterior wall 22a and is configured to face said guiding mean <NUM>, and preferably also to face the interior surface 12b of the movable window pane <NUM> as shown in the figure.

The interior wall 22b carries a second sealing lip <NUM> which is configured to be in sealing contact with the guiding mean <NUM>, and a third sealing lip <NUM> which is configured to be in sealing contact with the interior surface 12b of the movable window pane <NUM>.

Sealing lips <NUM>, <NUM> and <NUM> may be coated with antifriction layers F1.

In another example, only the first and the third sealing lips may be provided (no sealing is then provided on the guiding mean <NUM>).

The profile <NUM> may comprise at least one U-shaped metallic rail embedded or encapsulated into a polymeric covering. This rail may include a first branch extending into the exterior wall 22b, a second branch extending into the interior wall 22a, and a connecting branch extending into the lateral wall 22c.

The profile <NUM> and its polymeric covering may be made by co-extrusion. The sealing lips may be made of an elastically deformable material, such as for example EPDM or thermoplastic. These lips may be realized by over-molding or co-extrusion. Of course, the profile <NUM> might not comprise metallic rail and might therefore comprise only a polymeric material. The polymeric or covering material of the profile <NUM> may be a thermoplastic or an elastomer thermoplastic, such as for instance polypropylene. The over-molded material is for instance made of thermoplastic, elastomer thermoplastic, EPDM, SEBS, etc..

As shown in <FIG>, the first portion 142a of the over-molded material <NUM> has a first thickness E1 which is constant along a major portion of this first portion. The thickness E1 of this first portion 142A is measured in a direction which is perpendicular to the interior surface 14B of the fixed window pane <NUM> and which is also perpendicular to the exterior wall 22a.

The second portion 142b of the over-molded material <NUM> has a second thickness E2 which is constant along a major portion of the second portion. The thickness E2 of this second portion 142b is measured in a direction which is perpendicular to the lateral wall 22c.

This second portion 142b has an outer face 142b1 which extends between the lateral wall 22c and the interior surface 14b and which includes a major portion which is inclined with respect to the interior surface 14b.

In the shown example, the over-molded material <NUM> is V-shaped and includes both portions 142a, 142b connected therebetween and forming together a tip 142c. The over-molded material <NUM> includes a protruding rib <NUM> on its tip 142c, this protruding rib <NUM> extending on the interior surface 14b (<FIG>).

In the example shown, the shape of the over-molded material is provided by the shape of the profile <NUM> which includes a tooth <NUM> or a fin (such as a shark fin) on its lateral wall 22c.

The tooth <NUM> includes a first surface 168a parallel to the interior surface 14b and aligned with the surface 22a1 of the exterior wall 22a, and a second surface 168b which is inclined with respect to the interior surface 14b. The function of tooth <NUM> is to create a constant offset between the second surface 168b and the outer face 142b1. The shape and location of the surface 168b will thus evolve according to the shape and location of the outer face 142b1. The thickness E2 of the second portion 142b may be measured in a direction which is perpendicular to this second surface 168b.

The tooth <NUM> is preferably fully embedded into the over-molded material so that the first portion 142a extends between the first surface 168a and the interior surface 14b and the second portion 142b extends between the second surface 168b and the interior surface 14b. The first surface 168a is planar and the second surface 168b is also planar in the example shown. This second surface 168b is preferably parallel to the outer face 142b1 to ensure that E2 is constant. The first and second surfaces 168a, 168b are therefore V-shaped in cross section in the example shown. The first and second surfaces 168a, 168b form an angle α or form a tip having an angle which is comprised between <NUM> and <NUM>°, and preferably between <NUM> and <NUM>°. In other words, the tooth <NUM> defines an angle α comprised between <NUM> and <NUM>°, and preferably between <NUM> and <NUM>°.

<FIG> show further embodiments of the invention.

The embodiment of <FIG> differs from the embodiment of <FIG> in that the second part 22ab of the exterior wall 22a is replaced by a protruding lip <NUM> which extends externally and which is in abutment against the interior surface 14b of the window pane <NUM>.

The protruding lip <NUM> and the protruding leg <NUM> may be made of the same material as the main material of the profile <NUM>. The first sealing lip <NUM> is made of a softer material.

The over-molded material <NUM> does not cover the peripheral edge 14cb. This is due to the presence of the protruding lip <NUM> which abuts against the pane <NUM> and avoid over-molded material <NUM> passing through the lip <NUM> and up to the edge 14cb.

As shown in the drawings, the protruding lip <NUM> and leg <NUM> may define together and with the pane <NUM> a space S' that is empty, i.e., that is not filled with over-molded material <NUM>.

The embodiment of <FIG> differs from the embodiment of <FIG> in that the tooth <NUM> defines a larger angle α of about <NUM>-<NUM>°. The V-shape of the over-molded material <NUM> has a similar angle.

The embodiment of <FIG> differs from the embodiment of <FIG> in that the tooth <NUM> defines a small angle α of about <NUM>-<NUM>°. The V-shape of the over-molded material <NUM> has a similar angle.

The embodiment of <FIG> differs from the embodiment of <FIG> in that the second surface 168b of the tooth <NUM> is curved and in particular is concave. The second portion 142b of the over-molded material <NUM> conforms to the shape of this second surface 168b and has a curved shape. Similarly, the outer face 142b1 of the over-molded material <NUM> is curved and concave to get a thickness E2 as constant as possible.

The embodiment of <FIG> differs from the embodiment of <FIG> in that the second surface 168b of the tooth <NUM> is curved an in particular convex. The second portion 142b of the over-molded material <NUM> conforms to the shape of this second surface 168b and has a curved shape. Similarly, the outer face 142b1 of the over-molded material <NUM> is curved and convex to get a thickness E2 as constant as possible.

The embodiment of <FIG> differs from the embodiment of <FIG> in that the metallic rail embedded or encapsulated into the polymeric covering includes a leg <NUM> at its edge opposite the connecting branch. This leg <NUM> extends outwardly and is interposed between the edges 12cd and 14cb.

The embodiment of <FIG> differs from the embodiment of <FIG> in that over-molded material <NUM> comprises a third portion 142c, the first portion 142a extending between the third and second portions 142c, 142b.

The third portion 142c extends on the peripheral edge 14cb of the fixed pane <NUM>. The third portion 142c is perpendicular to the first portion 142a and extends outwardly from the end of the first portion 142a which is opposite to the second portion 142b. The third portion 142c covers entirely the peripheral edge 14cb in the example shown.

Therefore, the profile <NUM> is not directly in contact with the pane <NUM>. Its exterior wall 22b is remote from the interior surface 14b and is separated therefrom by the over-molded material <NUM>.

The first sealing lip <NUM> of the profile <NUM> is configured to abut against edge 12cd. The third portion 142c and the sealing lip <NUM> are both located between the edges 14cb and 12cd.

As shown, the third portion 142c may include an end which is coplanar with said exterior surfaces of said panes <NUM>, <NUM>.

The embodiment of <FIG> further differs in that the antifriction layer on the exterior surface of the interior wall 22a of the profile <NUM> is replaced by a co-extruded thermoplastic material and/or a cellular or foam material F2. This material is used to prevent rattle noise/tapping noise during door slam. The material F2 has for instance a shore A hardness of about <NUM>-<NUM> and/or a coefficient of friction less than about <NUM>,<NUM>. All the embodiments described above may have such material in the groove <NUM> instead of one of the antifriction layers F1.

In another embodiment shown in <FIG>, the third portion 142c of <FIG> may be combined with the leg <NUM> of any of the preceding embodiments (<FIG>) and may therefore be interposed between the peripheral edge 14cb of the pane <NUM> and this leg <NUM>.

Generally speaking, the third portion 142c is advantageous because it allows simplifying the mold that is used to perform the encapsulation. Moreover, it enhances the sealing during molding at the connecting area between the edges 14cb, 14ca (cf.

In another embodiment shown in <FIG>, the tooth <NUM> is made of a material which is different from the main (co-extruded or covering) material of the profile <NUM>. For instance, the main material of the profile <NUM> is harder than the material of the tooth <NUM>. The main material is for instance a PP. The material of the tooth <NUM> may have a Shore A hardness of between <NUM>-<NUM>, and for instance of about <NUM>. The material of the tooth <NUM> is for instance a TPE.

The protruding leg <NUM> and the protruding lip <NUM> may also be made of a material which is different from the main material of the profile <NUM>. The materials of the leg <NUM>, of the lip <NUM> and of the tooth <NUM> may be the same.

Even if the tooth <NUM> and/or the protruding leg <NUM> and/or the protruding lip <NUM> may be made of different material, they are preferably made by co-extrusion with the profile <NUM>. Use of a softer material for the protruding leg <NUM> for instance enhances the molding operation.

The second portion 142b extends on the tooth <NUM> and has an end linked to the profile <NUM>. This portion 142b has a constant thickness E2 up to this end.

In the embodiment of <FIG>, both branches of the metallic rail of the profile <NUM> are straight while in the embodiments of <FIG> the exterior branch of the metallic rail is slightly inclined and has an end opposite its lateral branch which protrudes inwardly.

Claim 1:
An encapsulated fixed window module (<NUM>) for a motor vehicle, comprising:
a fixed window pane (<NUM>) having an exterior surface (14a), an interior surface (14b), and a peripheral edge (14c) extending between said exterior and interior surfaces (14a, 14b),
at least one division post extending along at least a portion of said peripheral edge (14c), said division post comprising a first longitudinal profile (<NUM>) which is U-shaped in cross section and which has an exterior wall (22a), an interior wall (22b), and a lateral wall (22c) connecting said exterior and interior walls (22a, 22b), said first profile (<NUM>) defining a longitudinal groove (<NUM>) configured to receive a guiding mean (<NUM>) carried by a movable window pane (<NUM>), said exterior wall (22a) facing said interior surface (14b), and
an over-molded material (<NUM>) securing said first profile (<NUM>) to said fixed window pane (<NUM>), said over-molded material (<NUM>) comprising a first portion (142a) extending between said exterior wall (22a) and said interior surface (14b) and a second portion (142b) extending between said lateral wall (22c) and said interior surface (14b),
said first and second portions (142a, 142b) being connected one to the other, said first portion (142a) having a first thickness (E1) which is constant along a major portion of said first portion (142a), said second portion (142b) having an outer face (142b1) which extends between the lateral wall (22c) and said interior surface (14b) and which includes a major portion which is inclined with respect to said interior surface (14b),
characterized in that
said second portion (142b) has a second thickness (E2) which is constant along a major portion of said second portion (142b).