EP2284350A2 - Threshold of sliding closure frame comprising a heat shield and a hidden drain - Google Patents

Abstract

The device has a runoff profile (7) mounted on a U-shaped heat shield forming profile (5) so as to form a cover for the heat shield forming profile. A longitudinal edge of the cover extends to certain distance from the heat shield forming profile for forming a longitudinal evacuation opening (9) for evacuation of runoff water. The runoff profile has a T-shaped section whose vertical part assures connection with the heat shield forming profile.

Description

• ledit profilé de support étant un profilé à rupture de pont thermique, comportant au moins deux rails métalliques, ces deux rails étant assemblés au moyen d'une liaison complète par deux barrettes intermédiaires en matériau isolant, le profilé de support possédant une section généralement en forme de U,
• le profilé formant bouclier thermique étant réalisé en matériau isolant, et monté entre les deux rails, pour former un logement central longitudinal de recueillement des eaux de ruissellement.

The present invention relates to a sliding closure frame threshold, comprising at least one support profile on which is mounted a heat shield profile, water drainage holes being provided in said heat shield profile,

• said support profile being a thermal break profile, comprising at least two metal rails, these two rails being assembled by means of a complete connection by two intermediate strips of insulating material, the support section having a generally shaped section from U,
• the heat shield profile being made of insulating material, and mounted between the two rails, to form a longitudinal central housing for collecting runoff water.

A sliding frame with a profile forming a heat shield is known from the document EP 1 783 312 . In this document, the heat shield function is provided by an insulating element disposed between the branches of a U-shaped section. However, this document, which relates to an application by mounting such a structure, does not deal with the problem of drainage of the sliding closure frame threshold.

The document is also known EP 0 495 682 which relates to a sliding threshold having a brush-like structure disposed between the sliding rails or the like. Such a type of brush has the disadvantage of being poor thermal insulation and not easy maintenance.

• l'eau de ruissellement externe s'écoule à travers une fente longitudinale réalisée sur la surface plate supérieure du seuil, dans un canal collecteur interne supérieur, et
• s'écoule ensuite à travers des ouvertures internes réalisées dans le fond du canal collecteur interne supérieur, dans un canal collecteur interne inférieur en fond de seuil, avant de s'écouler à l'extérieur du seuil à travers des ouvertures latérales de celui-ci. Dans le mode de réalisation pratique du seuil selon ce document, ce seuil est constitué d'un profilé métallique de base comportant une partie creuse de guidage, le profilé de base étant réalisé en alliage d'aluminium ou analogue. Sur le profilé de base, sont ajustés deux profilés de surface supérieure constitutifs des deux rails de roulement pour les deux vantaux mobiles du coulissant. Les deux rails supérieurs de roulement sont réalisés séparément du profilé de base, et assurent également la fonction de rainure collectrice de l'eau de ruissellement. La réalisation séparée des deux profilés supérieurs plats à fonction de rail permet d'adapter le seuil à différents vantaux en réalisant des profilés de rails adaptés en fonction des besoins. Le seuil selon ce document ne fait état d'aucun bouclier thermique, ni d'aucune structure à rupture de pont thermique, et n'aborde pas l'isolation thermique combinée avec la fonction de seuil de coulissant et avec la fonction de drainage du seuil.

The document is also known US 2003/0177699 which refers to a sliding closure separating the external environment from the inside of a construction, having a flat surface threshold. The proposed closure improves the sealing barrier in this configuration, at the threshold. This closure is part of an application framework that aims to remove any rail protruding from the threshold for that the latter offers a flat surface devoid of any market for people crossing the threshold. The threshold according to this document offers a drainage solution to improve the sealing in this case of flat surface of the threshold, including in case of wind applying pressure on the closure. The threshold according to this document presents in the whole a drainage via the interior of the threshold as follows:

• the external runoff flows through a longitudinal slot made on the upper flat surface of the threshold, into an upper internal collecting channel, and
• then flows through internal openings made in the bottom of the upper internal collecting channel, into a lower internal collector channel at the bottom of the threshold, before flowing out of the threshold through side openings thereof . In the practical embodiment of the threshold according to this document, this threshold consists of a basic metal section comprising a hollow guide portion, the base section being made of aluminum alloy or the like. On the base profile, are fitted two upper surface profiles constituting the two rails for the two sliding leaves of the sliding. The two upper running rails are made separately from the base profile, and also act as a collecting groove for the runoff water. The separate realization of the two flat rails with rail function makes it possible to adapt the threshold to different leaves by producing rail profiles adapted to the needs. The threshold according to this document does not mention any thermal shield, nor any structure with thermal break, and does not address the thermal insulation combined with the sliding threshold function and the threshold drainage function. .

In the state of the art, a sliding frame threshold comprises a metal section on which a generally U-shaped thermal insulating section is mounted between the two rails. This U-shaped insulating profile comprises runoff evacuation openings, generally located at the base of the lateral branches of the U; after having passed through these evacuation openings of the insulating section, the water is also drained by openings, made through the side walls of the outboard metal profile outwardly, possibly with discharge nozzles placed on the outer face of the metal section to slow down the air inlet and the discharge of the evacuated water.

This type of sliding sill threshold evacuation is apparent and therefore unsightly. In addition, this type of evacuation has the disadvantage of offering only a minimal resistance to the discharge pressure from the outside wind.

The invention aims to overcome these disadvantages.

More particularly, the invention aims to provide a threshold having heat shield functions and evacuation invisible or at least completely discrete.

• ledit profilé de support étant un profilé à rupture de pont thermique, comportant au moins deux rails métalliques, ces deux rails étant assemblés au moyen d'une liaison complète par deux barrettes intermédiaires en matériau isolant, le profilé de support possédant une section généralement en forme de U,
• le profilé formant bouclier thermique étant réalisé en matériau isolant, et monté entre les deux rails, pour former un logement central longitudinal de recueillement des eaux de ruissellement,
  ledit seuil étant caractérisé par le fait qu'il comprend un profilé de ruissellement associé au dit profilé formant bouclier thermique de manière à former un capot pour ledit profilé isolant formant bouclier thermique, au moins un bord longitudinal dudit capot s'étendant à une certaine distance de l'un desdits profilé de support ou profilé formant bouclier thermique qui lui fait face pour former une ouverture longitudinale d'évacuation des eaux de ruissellement.

To this end, the subject of the invention is a sliding closure frame threshold, comprising at least one support profile on which is mounted a heat shield profile, water drainage holes being provided in said heat shield profile. ,

• said support profile being a thermal break profile, comprising at least two metal rails, these two rails being assembled by means of a complete connection by two intermediate strips of insulating material, the support section having a generally shaped section from U,
• the heat shield profile being made of insulating material, and mounted between the two rails, to form a central longitudinal recess for collecting runoff water,
  said threshold being characterized in that it comprises a runoff profile associated with said heat shield profile so as to form a cover for said heat shield insulating profile, at least one longitudinal edge of said cover extending at a certain distance one of said support profile or heat shield profile which faces it to form a longitudinal opening for discharging runoff water.

The invention has a number of advantages over the state of the art.

First, the runoff profile completing the heat shield profile constitutes a continuous longitudinal opening and yet discrete discharge of runoff water that arrives on the shield. The continuity of this longitudinal opening allows to confer a discretion of the evacuation allied to the search for a certain aesthetics.

Moreover, this arrangement does not affect the thermal insulation insofar as the longitudinal opening is only of small transverse dimension. The standard allows up to 2 mm gap, the heat flow is not high enough to affect the thermal insulation function.

Under the runoff profile, runoff outlets are made in the heat shield insulating profile, so that they are not visible when the runoff profile is placed on the heat shield insulating profile. Then, evacuation openings are made in the support profile in a conventional manner through its side walls or on horizontal webs of this profile so as not to reveal an opening in the visible face.

Another advantage of the solution of the invention consists in recovering the total volume of the central longitudinal housing for collecting runoff from the heat shield, under the runoff profile, for the storage of runoff water, because the longitudinal opening allows a water evacuation almost without resistance, which prevents this water to stagnate above the surface of the runoff profile waiting to be evacuated through openings of smaller passage sections. This is the amount of water acceptable by the overflow profile above the rails.

Another advantage of the invention consists in reducing the "bubbling" (reflux pressure of the discharged water, against the pressure of the outside wind which may tend to prevent this evacuation by gravity), thanks to an advantageous arrangement of the holes on a horizontal surface involving the possibility of forming baffles, whereas in the state of the art, the evacuation by the side walls implies being in direct line with the external holes in the wind.

In a particular embodiment, said heat shield profile mounted between the two rails, has a generally U-shaped section open towards the outside to form a longitudinal central recess U, for collecting runoff water.

By "open outward" is meant an open section on the opposite side to the support profile, that is, the U is open towards the sliding closure frame.

In a particular embodiment, said runoff profile and said heat shield profile form two distinct profiles dissociated associated with each other by means of removable connection means of the clipping type.

This arrangement facilitates the realization of the openings by punching whereas if the runoff profiles and heat shield are made in a single and necessarily rigid monobloc necessarily insulating profile, the drainage openings must be machined by milling which is more expensive.

In addition, the solution of making the two profiles of runoff and heat shield in two separate sections, allows for these two profiles in different materials: insulation for the heat shield profile and for example metal for the runoff profile, without damaging the thermal insulation because the distance according to the invention between the runoff profile and the profile which faces it avoids that a thermal bridge is formed. The metallic realization of the runoff profile allows to offer new aesthetics of the threshold (concealed drainage and aesthetic agreement with the main metal threshold profile) without harming the thermal insulation.

In a particular embodiment, said runoff profile and said heat shield profile form a single profile in one piece made of insulating material.

In a particular embodiment, said hood is coated with a layer of a material different from that constituting said flow profile.

This feature makes it possible to use the same material for the runoff profile and the heat shield while giving the appearance of the runoff profile of another constituent material.

In a particular embodiment, said runoff profile and said heat shield profile forming a single piece of single piece made of insulating material, are associated by a connection to a degree of freedom in longitudinal rotation, combined with additional means fixing one profile on the other.

This feature offers the advantages of two separate profiles to facilitate manufacturing, including the realization of drainage openings, while also offering the advantages of a profile made in one piece, especially in terms of assembly and logistics without having the disadvantages in terms of manufacturing.

In a particular embodiment, said runoff profile and said heat shield profile form a single piece made of insulating material integrally, the profiled runoff portion being fixed relative to the profiled portion forming a heat shield.

In a particular embodiment, said runoff section has a generally T-shaped section, the edge of the vertical portion provides the connection with the heat shield profile and the horizontal portion ensures the reception of runoff.

More particularly, the T-shaped section of the flow profile may be double vertical bar.

In particular embodiments, the longitudinal edge of said hood may face a longitudinal wall of the support profile or a longitudinal wall of the heat shield profile.

Also in a particular embodiment, each of the longitudinal edges of said cover extends at a distance from the profile which faces it.

In a particular embodiment, the upper surface of said hood formed by said runoff profile is located substantially at the base of two inner walls of the two metal rails, facing each other, the upper part of the rails being projecting above the upper surface of said hood.

This characteristic makes it possible to optimize the threshold space reserved for runoff water and the space of the said threshold reserved for the lower part of the sliding openings, in the presence of the runoff profile.

• la figure 1 est une vue en perspective éclatée d'un seuil selon l'invention avant assemblage de profilés, selon un premier exemple de mode de réalisation,
• la figure 2 est une vue similaire à la figure 1 avec le seul profilé de ruissellement non encore assemblé,
• la figure 3 est une vue similaire aux figures 1 et 2 avec les profilés assemblés,
• La figure 4 représente une vue en coupe transversale de la figure 3,
• La figure 5 représente une vue en coupe transversale d'un deuxième exemple de mode de réalisation d'un seuil selon l'invention, avec des coulissants représentés partiellement sur les rails,
• La figure 6 représente une vue en coupe transversale d'un troisième exemple de mode de réalisation d'un seuil selon l'invention,
• La figure 7 représente une vue en coupe transversale d'un quatrième exemple de mode de réalisation d'un seuil selon l'invention, avec des coulissants représentés partiellement sur les rails,
• La figure 8 représente une vue en coupe transversale d'un cinquième exemple de mode de réalisation d'un seuil selon l'invention, avec des coulissants représentés partiellement sur les rails.

Several embodiments of the invention will now be described, by way of nonlimiting example, with reference to the appended diagrammatic drawings in which:

• the figure 1 is an exploded perspective view of a threshold according to the invention before assembling profiles, according to a first exemplary embodiment,
• the figure 2 is a view similar to the figure 1 with the only runoff profile not yet assembled,
• the figure 3 is a view similar to figures 1 and 2 with the assembled profiles,
• The figure 4 represents a cross-sectional view of the figure 3 ,
• The figure 5 represents a cross-sectional view of a second exemplary embodiment of a threshold according to the invention, with sliders partially shown on the rails,
• The figure 6 represents a cross-sectional view of a third exemplary embodiment of a threshold according to the invention,
• The figure 7 represents a cross-sectional view of a fourth exemplary embodiment of a threshold according to the invention, with sliders partially shown on the rails,
• The figure 8 represents a cross-sectional view of a fifth exemplary embodiment of a threshold according to the invention, with sliders partially shown on the rails.

The following immediate description relates to Figures 1 to 4 which relate to the first embodiment of the threshold according to the invention.

We see at the figure 1 a support section 1 with a thermal break of known type, constituted in the example of two metal rails 2 for sliding sliding frames, these rails being assembled by means of a complete connection, for example by crimping, by two intermediate bars 3 made of insulating material, for example a plastics material of polyamide type or the like. The support profile 1 here has a generally U-shaped section in any known manner.

The bars 3 form webs 4 perpendicular to the connecting webs even with the rails 2, limiting the heat exchange by convection, between the outer and inner media, separated by the sliding frame.

A profile 5 forming a heat shield, also and in the example of generally U-shaped section, is clipped between the rails 2 of the support profile 1, as more particularly shown in FIG. figure 4 for the example, to form a longitudinal central recess U, for collecting runoff water, whose vertical or substantially vertical branches define vertical or substantially vertical walls in the example aligned between the branches of the U of the section 5 and the inner walls vis-à-vis the metal rails 2. The profile 5 is made of insulating material, for example a polyamide type plastic or the like. The bottom of the U of the profile 5 advantageously comprises on its horizontal surface drainage holes 6 whose function will be described below.

The figure 2 shows the profiles 1 and 5 assembled.

Finally, a runoff profile 7 is clipped onto the profile 5.

The runoff profile 7, for example metal, but it can be made of plastic in an alternative manner as will be with the description of the third, fourth and fifth examples of the threshold according to the invention using the Figures 6 to 8 , in particular made of polyamide or the like, has a generally T-shaped section with a double vertical bar 8 whose edges cooperate with a rib 9 formed at the bottom of the profile 5 and placed between the two vertical bars 8 as shown in FIG. figure 4 more particularly. When the profile 7 is mounted on the profile 5, the profile 7 thus hides the drainage holes 6 as shown in FIG. figure 3 . The runoff profile 7 and the heat shield profile 5 advantageously form two distinct profiles dissociated associated with each other by means of removable connection means of the clipping type.

The drainage orifices 6 are arranged on either side of the rib 9 and also on either side of the vertical bars 8 of the flow profile 7. The drainage orifices 6 each adopt a length and are distributed along the section 5, according to standards and needs.

The horizontal bar of the T formed by the section of the flow profile 7 has a width such that the two opposite transverse edges of the plate 10 extending longitudinally and forming the upper part of the profile 7, extend at a distance e, for example, preferably between 1 mm and 2 mm, from the flange of the U-profile 5 or the rail 2 facing them, here in the example at the boundary between the rails 2 and the profile 5, thus defining a longitudinal interval 11 for discharging the runoff water that ends on the plate 10.

The distance e may be equal or substantially equal on each side of the plate 10 or different. The plate 10 may for example be convex according to its transverse profile, the convexity being turned upwards, as shown in the figures, in order to facilitate the flow of water towards the longitudinal openings thus formed between the edges of the plate 10 and the rails 2 and / or the U-shaped section 5.

The interval 11 thus formed ( figures 3 or 4 ) forming said two longitudinal discharge openings, allows the flow of runoff under the section 7, more precisely under the plate 10 of this, then, through the drainage holes 6 of the profile 5 advantageously formed on the horizontal surface of this profile 5 and under the plate 10, under the U-shaped base of the profile 5 to the profile 1 from which they are then removed outwardly in the usual way (not shown) through its side walls of the support profile 1.

Openings 12 are made in the case in point, advantageously in vertical ribs 13 formed under the U-section of the section 5, as shown, between the base thereof and the bottom of the U of the section 1 to create a passage for the water below the drainage holes 6 to conventional openings (not shown) made in the section 1 so that finally the water is rejected in front. It should be noted that as shown on the figure 1 , the openings 12 and the drainage holes 6 may advantageously be offset longitudinally to participate advantageously in the constitution of flow baffles.

It should be noted that the U-profile comprises in the example two other longitudinal vertical ribs 14 parallel to the two ribs 13 and placed between them, whose function in the example is to form a support of the profile 5 on the profile 1, more precisely and advantageously on the insulating strips 3. These longitudinal ribs 14 preferably comprise openings 15 distributed along them, like those of the ribs 13, and aligned longitudinally or offset with them, to ensure a path of the evacuation of water from one rail 2 to the other on the bottom of the U.

The openings 12 and 15 are made by means of indentations of the lower edge of the corresponding ribs 13 and 14 respectively, so that the water can travel on the bottom of the U of the profile 1. It should be noted that the lower edge of the ribs 13 may not be in contact with the bottom of the U of the profile 1 as shown on the figure 4 .

Such a flow of water through the drain holes 6 and described flow openings 12 forms a set of baffles on a horizontal path and on a combined vertical path of water, advantageously reducing the "bubbling" pressure as explained above.

The second exemplary embodiment of a threshold according to the invention will now be described with the help of the figure 5 . In this second example, the elements that are identical or similar, at least functionally, to those of the first example respectively have the same references. The example of figure 5 is similar to the first embodiment of the Figures 1 to 4 , except for the plate 10 which is here coated with a layer 20 of a material different from that constituting the flow profile 7. This layer 20 covers the visible upper surface of the plate 10, as shown. The layer 20 furthermore acts as a hubcap and can be made for example in the form of a metal sheet in the form of a longitudinal strip of convex cross-section, the two longitudinal edges of which are curved so as to form longitudinal retention hooks. surrounding the transverse ends of the plate 10 along the length thereof, as shown in FIG. figure 5 . The runoff profile 7 may advantageously be made of plastic material. The convexity of the sheet forming the layer 20 is rotated in a manner similar to the convexity of the plate 10 of the first example. Thus, the expensive and thermally conductive material is reduced to a sheet of minimum thickness as needed. According to this embodiment, the distance e is no longer measured from the transverse edges of the plate 10 as for the first example, but from the transverse edges of the layer 20. The layer 20 can be manufactured to be associated, by removably example, the runoff profile 7 by longitudinal sliding, the visible upper surface of the layer 20 constituting the drainage water runoff surface on the runoff profile.

The third exemplary embodiment of a threshold according to the invention will now be described with the help of the figure 6 . In this third example, elements identical or similar, at least functionally, to those of the first and second examples have respectively the same references. The example of figure 6 is similar to the second embodiment according to the figure 5 , with the exception of the runoff profile 7 and the heat shield profile 5 which form in this example a single profile integral (monobloc) made of insulating material. In addition, the runoff profile 7 or runoff portion of the single profile, and the profile 5 or heat shield portion of the single profile, are associated by a link with a degree of freedom in longitudinal rotation, combined with additional means for fixing the profile. one profile on the other. One of the transverse edges of the plate 10 is connected, in the region of the end of the edge advantageously located on the lower surface of the plate 10, to the part facing the heat shield section 5, for example the upper region of a branch of the U, by a web 21 of flexible material, thin, which advantageously extends along the length of the profile 5, 7 monobloc, to form a hinge pivoting or articulation, along a longitudinal axis of the runoff portion 7 with respect to the heat shield portion 5. The trickle portion 7 is fixed, after pivoting, to the heat shield part 5, like the first and second embodiments, for example by clipping via the lower edge of at least one of the two vertical bars 8 of the T which cooperates with the rib 9 formed at the bottom of the profile 5 and placed in the example between the two vertical bars 8, preferably the bar 8 farthest from the web 21 as shown on the figure 6 . The fastening of the web 21 on the lower surface of the plate 10 is made such that this fastening advantageously allows the sliding of the sheet 20 on the runoff portion 7, as in the example of the figure 5 . The sail 21 may be longitudinally interrupted at several points (not shown) to ensure the flow of runoff through it; the sail 21 may also consist of a plurality of fine links distributed along the runoff profile so that the longitudinal opening is preponderant in front of the space occupied by the links.

The fourth exemplary embodiment of a threshold according to the invention will now be described with the help of the figure 7 . In this fourth example, the elements that are identical or similar, at least functionally, to those of the other examples respectively have the same references. The example of figure 7 is similar to the third exemplary embodiment according to the figure 6 with the exception of layer 20 which is absent; the convex transverse section of the plate 10 is similar to that of the first example according to the Figures 1 to 4 . The runoff profile 7 and the heat shield profile 5 form a single profile in one piece made of insulating material.

The fifth exemplary embodiment of a threshold according to the invention will now be described with the help of the figure 8 . In this fifth example, the elements that are identical or similar, at least functionally, to those of the other examples respectively have the same references. According to this fifth example, the runoff profile 7 and the heat shield profile 5 form an integral profile made of insulating material in a single piece, the runoff profile 7 or runoff portion being fixed relative to the profile 5 forming heat shield or heat shield part of the monobloc profile. As shown, the single piece profile takes the form of a tubular section, preferably honeycomb, made of substantially rigid plastic material. The profile 5, 7 insulating monoblock is substantially indeformable according to normal forces applicable to it in normal use. The profile 5, 7 insulating monoblock is slid longitudinally into the U of the support profile 1. The heat shield portion 5 adopts a U-shaped surmounted by the portion 7 of runoff attached to the base of the U, in the example by three vertical ribs . The runoff portion comprises a convex upper plate 10 like the other described embodiments. The single profile 5, 7 monobloc insulation is wedged between the rails 2 by the base of the U of the shield portion 5 which is adjusted between the two vertical walls of the rails of the U formed by the support profile 1. The base of the heat shield shaped of U adopts the shape of a flat plate dimple which marries the surface of the U base formed by the support section 1 straddling the thermally insulating bars so as to cover them. The vertical or substantially vertical branches of the U formed by the heat shield portion 5 extend to come close to or in contact with the return walls of the rails toward the inside of the U, as shown.

In general with respect to all the described examples of threshold according to the invention, when the heat shield 5 is mounted in the support section 1 with thermal break, it is found that all of these two elements form a longitudinal central U-shaped recess for collecting runoff water, whose vertical or substantially vertical branches define vertical or substantially vertical walls, in the examples aligned or substantially aligned between the branches of the U of the profile 5 or section part 5 and the inner walls vis-à-vis the metal rails 2.

The upper surface of the plate 10 of the flow profile 7 is advantageously and substantially at the level of the base of the inner walls vis-à-vis the metal rails 2, as shown in FIGS. Figures 3 to 8 , the upper part of the rails 2 being protruding above the hood formed by the runoff profile. This makes it possible to preserve a longitudinal U-shaped space remaining when the runoff profile 7 or the runoff portion of the insulating profile is mounted and associated with the heat shield. This remaining U-shaped space has the function of allowing, in a known manner, the positioning inside this space, of the base of the sliding openings, carrying the friction brushes against the inner walls opposite the rails, as represented on the figures 5 , 7 , and 8 .

The set of threshold structure thus arranged and described above makes it possible to provide a thermal break threshold for sliding openings mounted on projecting rails, whose thermal insulation performance is very good, combined with a drainage system. hidden runoff and various aesthetic possibilities of the threshold.

Claims (13)

Sliding closure frame threshold, comprising at least one supporting profile (1) on which a heat shield profile (5) is mounted, water drainage holes (6) being provided in said shield profile (5) thermal, said support profile (1) being a thermal break profile, comprising at least two metal rails (2), these two rails being assembled by means of a complete connection by two intermediate bars (3) made of insulating material, the support profile having a generally U-shaped section, the heat shield profile (5) being made of insulating material, and mounted between the two rails, to form a longitudinal central recess for collecting runoff water,
said threshold being characterized in that it comprises a runoff profile (7) associated with said heat shield profile so as to form a cover for said heat shield insulating profile, at least one longitudinal edge of said cover extending to a distance (e) of one of said supporting profile (1) or profile (5) forming a heat shield facing it to form a longitudinal discharge opening (9) of runoff water. The threshold of claim 1, wherein said heat shield profile (5) mounted between the two rails has a generally U-shaped section open outwardly to form a longitudinal U-shaped central recess for collecting runoff water. Threshold according to claim 1 or 2, wherein said runoff profile (7) and said profile (5) forming a heat shield form two distinct profiles dissociated, associated with each other by means of removable connection means, clipping type . Threshold according to claim 1 or 2, wherein said runoff profile (7) and said profile (5) forming a heat shield form a single profile in one piece made of insulating material. Threshold according to claim 3 or 4, wherein said cover is coated with a layer (20) of a material different from that constituting said runoff profile (7). Threshold according to claim 4 or 5, wherein said runoff profile (7) and said profile (5) forming a heat shield are associated by a link with a degree of freedom in longitudinal rotation, combined with additional means of fixing a profiled on the other. Threshold according to claim 4 or 5, wherein said runoff profile (7) and said profile (5) forming a heat shield form an integral profile made of insulating material integrally, the profiled part of runoff being fixed by relative to the shaped part forming a heat shield. Threshold according to one of the preceding claims, wherein said runoff profile (7) has a generally T-shaped section, the edge of the vertical portion provides a connection with the heat shield profile and whose horizontal portion provides the receipt of runoff. The threshold of claim 8, wherein the T-shaped section of the runoff profile is a double vertical bar (8). Threshold according to one of the preceding claims, wherein the longitudinal edge of said cover faces a longitudinal wall of the support profile (1). Threshold according to one of the preceding claims, wherein the longitudinal edge of said cap faces a longitudinal wall of the heat shield profile (5). Threshold according to one of the preceding claims, wherein each of the longitudinal edges of said cover extends at a distance (e) from the body facing it. Threshold according to one of the preceding claims, wherein the upper surface of said cover formed by said runoff profile (7) is located substantially at the base of two inner walls of the two metal rails (2), vis-à- screw the one of the other, the upper part of the rails (2) being projecting above the upper surface of said cover.

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