EP3196395B1 - Door with a handle profile - Google Patents

Description

The present invention relates to a door or a window with a handle profile according to the preamble of claim 1.
Such a door is out of the FR 2 951 769 A1 known. The door handle stands out of the plane he door. The statics of the door is adversely affected by the handle.

FR 2 951 769 A1 discloses all features of the preamble of claim 1.

In the DE 20 2008 001 663 U1 discloses a door having a frame on which a wing is rotatably mounted. The wing has a handle bar, which is arranged on the outside of the wing and which is embedded in the wing. The term "embedded" here means that the handle bar is surrounded by an insulating material, in particular a foamed plastic and is formed by formed with undercut grooves in which the insulating material, positively held in the insulating material. The handle bar is thus attached only at their end faces on a circumferential inner frame of the wing.
Such an arrangement or embedding has a detrimental effect on the rigidity of the handle bar, since the handle bar is deformed elastically by actuation forces virtually every time the handle bar is actuated. This deformation leads to a bending moment acting on the handle. The tensile and compressive forces associated with this bending moment must be endured by the connection of the handle bar with the insulating material permanently. It is therefore possible that the connection can fail locally by high actuation forces and the connection between the handle and the insulating material is therefore given up locally. In an extreme process, this can lead to the connection between the insulating material and the handle bar being completely abandoned, thereby completely disengaging the handle from the wing and thus destroying the entire wing.
In the DE 60 2005 001 154 T2 discloses a door with integrated handle or with integrated fastener for releasably securing a handle. The door has a wing or, in the case of a door, a door leaf having front and rear fillings integrated into the wing and at its peripheral edges are attached by soffit parts to each other. The front and rear panels form a front surface and a rear surface of the door, respectively, the handle extending from the front surface to the rear surface of the wing and configured to allow users to open / close the door. The handle is a substantially straight elongate metallic profile that extends over substantially an entire extent of the front and rear surfaces, thus dividing the wing into separate wing segments which extend on opposite sides of the handle. A disadvantage of the solution after the DE 60 2005 001 154 T2 is the bad thermal insulation. In addition, there is a considerable manufacturing effort, since in the wing production relatively many items are to be added. In addition, the statics of the door is adversely affected by the handle.

The invention therefore has the task of improving the generic state of the art.

The present invention solves this problem by the subject matter of claim 1.

As a result, the actuating forces of the grip profile and the resulting bending moments are introduced into the wing frame composite profile in an advantageous manner that permanently withstand these forces or moments due to its high rigidity.

Preferably, the handle profile on a handle recess profile, which has a hollow chamber. The recessed grip profile is preferably a metallic recessed grip profile.

According to a development, it is provided that the grip profile is designed as a thermally insulated composite profile. By this measure is advantageously prevented that a thermal bridge is created by the insertion of a handle profile in the wing in this, which adversely affects the thermal insulation properties of the wing.

Due to the structure of the handle profile as a thermally insulated composite profile, wherein the handle profile is composed of several closed part profiles, which are interconnected by insulating webs, the resistance to deformation of the handle profile is increased, so that the handle profile consequently has a high rigidity.

In one embodiment variant of the invention, the grip profile or the grip profile has an opening for a profile closure cylinder or a profile closure cylinder. This makes it possible in an advantageous manner to use the handle profile for the production of a casement Holmes.

In a further embodiment of the invention, the handle profile in his recessed grip on one or more bulbs, such. one or more LEDs. As a result, the grip profile and its surroundings can be illuminated in the dark in an advantageous manner, so that no additional illumination of the door or an entrance area is required to open the door with a key.

According to a subclaim, it is provided that the handle profile on its side facing the filling has a compatible or the same topology - i. a compatible or preferably even the same geometry with the same functional areas as grooves, etc. - has, as the adjoining it sash composite profile on its side facing the filling. Thereby, it is advantageously possible to use various fillings, e.g. to install an insulating glazing or a sandwich panel with a heat-insulating core made of foamed plastic on the handle profile, so that the handle profile with respect to various fillings is also universally applicable, as a corresponding wing frame composite profile. In addition, can be carried out by the same topology on the filling side facing the handle profile and wing frame composite profile an advantageous standardization of the connection geometry of the handle profile or on the wing frame composite profile of the filling.

Particularly advantageous in this context, if the handle profile has the same width as the wing frame composite profile.

Further advantageous embodiments of the invention can be found in the remaining subclaims.

Figur 1:

eine Tür, die einen Flügel- und einem Blendrahmen sowie ein Griffprofil und eine Füllung aufweist;

Figur 2:

eine Schnittdarstellung einer Tür mit einem Flügel- und einem Blendrahmenprofil sowie ein Griffprofil und eine Füllung nach Fig. 1;

Figur 3:

eine Ausschnittvergrößerung eines Flügelrahmenprofils in Schnittdarstellung nach Fig. 2;

Figur 4:

eine Ausschnittvergrößerung eines Blendrahmenprofils in Schnittdarstellung nach Fig. 2;

Figur 5:

eine Ausschnittvergrößerung eines erfindungsgemäßen Griffprofils in Schnittdarstellung nach Fig. 2;

Figur 6:

eine Ausführungsvariante einer Tür, die einen Flügel- und einem Blendrahmen sowie ein Griffprofil und eine Füllung aufweist.

Embodiments of the subject invention are illustrated in the drawings and will be described in more detail below. It shows:

FIG. 1:

a door having a wing and a frame and a handle profile and a filling;

FIG. 2:

a sectional view of a door with a wing and a frame profile and a handle profile and a filling according to Fig. 1 ;

FIG. 3:

a section enlargement of a sash profile in section according to Fig. 2 ;

FIG. 4:

a detail enlargement of a frame profile in section according to Fig. 2 ;

FIG. 5:

a detail enlargement of a handle profile according to the invention in a sectional view according to Fig. 2 ;

FIG. 6:

a variant of a door having a wing and a frame and a handle profile and a filling.

The Fig. 1 shows a door 1, which has a wing with a sash 2 and a frame 3. This is merely an example to understand. Alternatively to the in Fig. 1 1, the present invention can also be used in windows or the like. If the term "door" is used below, it can therefore also be replaced by a term window.

By a corner joint of two vertically or vertically aligned wing frame beams 4, 5 with an upper horizontal wing frame spar 6 an at least U-shaped (ie open on one side) frame of similar profiles is created. A lower horizontal wing frame spar 7 is here as one to the rest Wing frame members 4, 5, 6 geometrically different profile formed. The casement 2 can also be made circumferentially closed from wing frame beams 4, 5, 6, 7, which are each made of a single profile. The frame 3 of this door 1 has frame frame spars 8, 9, 10. Individual or all of the spars may be formed as thermally insulated composite profiles.

The wing frame members 4, 5, 6, 7, together with a filling 11, the wing 12. The wing 12 also has a grip profile 300 according to the invention. The filling 11 may e.g. an insulating glazing or a sandwich panel with a heat-insulating core made of foamed plastic. The handle profile 300 is disposed parallel to the vertical sash bars 4, 5 and has a length that is identical to the dimension of the filling 11 in its vertical extension direction.

In Fig. 2 is a a door 1 with a wing frame composite profile 100 and a frame composite profile 200, and the handle profile 300 and the filling 11 after Fig. 1 shown in section. For simplicity, only the part of the door 1 with the handle profile 300 is shown.

In the following, purely by way of example, a wing frame composite profile 100 and a frame composite profile 200 having in each case two metallic outer profiles 101, 102 or 201, 202 and in each case a metallic center profile 103 or 203 will be described. Alternatively, the casement composite profile 100 and / or the frame composite profile 200 may be constructed without the metal center section 103 or 203, so that in each case the two metallic outer profiles 101, 102 and 201, 202 are connected to each other only via a Isolierstegebene ,

In addition, in the following for the casement composite profile 100, the frame composite profile 200 and the handle profile 300 own reference numeric number ranges are used to identify analogous characteristics in the individual composite profiles 100, 200, 300 accordingly. This results however, in the frame composite profile 200 and the handle profile 300, a non-consecutive numbering of the reference numerals.

The sash composite profile 100 is detailed in FIG Fig. 3 and the frame composite profile 200 is detailed in FIG Fig. 4 so that the following description also applies to the illustrations in Fig. 3 or in Fig. 4 refers.

The sash composite profile 100 (see Fig. 2 and 3 ) has a first metallic outer profile 101, in which here at least one hollow chamber 104 is formed, and a metallic center profile 103, in which also preferably at least one hollow chamber 105 is formed. The hollow chamber 105 is designed so that it can accommodate a lock case (not shown here), via which the door 1 can be locked. The first metallic outer profile 101 is connected to the metallic center profile 103 via at least one or more first insulating webs (aligned parallel here) 106, 107. These insulating webs 106, 107 between the first metallic outer profile 101 and the metallic center profile 103 form a first insulating land zone I or plane. The first metallic outer profile 101 also has, on its side facing away from the first insulating land zone I, a groove 108.

The metallic center profile 103 has in each case on its sides, each in the x-direction (see coordinate system in Fig. 2 and Fig. 3 ), each having a groove 109, 110 with an undercut, wherein the grooves 109, 110 is here each designed as a groove 109, 110 with a substantially T-shaped cross-section. In the groove 109 here is a cover plate 111 is positioned and fixed, which has a with the groove 109 geometrically corresponding, integrally formed on the cover plate 111 foot 112 which engages in the groove 109 and is snapped into the groove 109. The geometric configuration of the undercut of the grooves 109, 110 may also be performed differently than T-shaped.

The metallic center profile 103 is connected to a second metallic outer profile 102, in which preferably at least one hollow chamber 113 is formed, via at least one or more second insulating webs (aligned parallel here) 114, 115 connected. This insulating webs 114, 115 between the metallic center section 103 and the second metallic outer profile 102 form a second insulating land zone II or plane.

The insulating webs 106, 107, 114, 115 have here-by way of example-no hollow chambers. Alternatively, however, the insulating webs 106, 107, 114, 115 may also have one or more hollow chambers or the insulating webs 106, 107, 114, 115 may be summarized by transverse webs to a kind of higher-level insulating profile.

The insulating webs 106, 107, 114, 115 are here-by way of example-arranged in a plane. Alternatively, it is also possible for the insulating webs 106, 107, 114, 115 to be offset horizontally relative to each other or vertically offset from one another. Likewise, a diagonal orientation of the insulating webs 106, 107, 114, 115 is possible.

The first insulating land zone I, which is formed between the first metallic outer profile 101 and the metallic center profile 103 by the insulating webs 106, 107, has a hollow chamber 116. The second insulating land zone II formed between the metallic center profile 103 and the second metal outer profile 102 by the insulating webs 114, 115 also has a hollow chamber 117.

Preferably, the insulating webs 106, 107, 114, 115 are web-shaped in cross-section.

The insulating webs 106, 107 of the first insulating land zone I here each have two thickened end sections 118. In this case, each of the end sections 118 preferably engages in a corresponding groove 119, which here is formed by a respective one of the metal profiles 101, 103. The respective end portion 118 preferably has a trapezoidal or triangular or wedge-shaped or L-shaped or rectangular cross-section. The respective groove 119 accordingly has a cross section with a corresponding cross section.

In order to obtain a shear-resistant and thus additionally non-positive connection between the respective end section 118 and the respective groove 119, it is advantageous to when the respective end portions 118 are set in the respective groove 119 by a forming process. Thereby, the respective end portion 118 of the insulating webs 106, 107 in the x and y directions with respect to the coordinate system in Fig. 2 and Fig. 3 established. In addition, the respective end portion 118 is also by a wire having an outer structure, such as knurling (not shown here) or other suitable joining method in addition in the z-direction with respect to the coordinate system in Fig. 2 and Fig. 3 or set in profile direction, so that in each case a shear-resistant connection is formed.

The insulating web 107 of the first insulating land zone I has a groove 120 with an undercut, wherein the groove 120 is designed here as a groove with a T-shaped cross-section. In the groove 120 here a sealing profile 121 is positioned and fixed, which has a with the groove 120 geometrically corresponding, integrally formed on the sealing profile 121 foot 122 which engages in the groove 120 and snapped into the groove 120. The geometric design of the undercut of the groove 120 may also be performed differently than T-shaped.

The insulating webs 114, 115 of the second insulating land zone II here each have a thickened end sections 118. In this case, each of the end sections 118 preferably engages in a corresponding groove 119, which here-by way of example-is formed by the metallic center section 103. Alternatively, the groove 119 may also be formed by the second outer profile 102. The respective end portion 118 preferably has a trapezoidal or triangular or wedge-shaped or L-shaped or rectangular cross-section. The respective groove 119 accordingly has a cross section with a corresponding cross section.

In order to obtain a shear-resistant and thus additionally frictional connection between the respective end portion 118 and the respective groove 119, it is advantageous if the respective end portions 118 are fixed in the respective groove 119 by a forming process. Thereby, the respective end portion 118 of the insulating webs 114, 115 in the x and y directions with respect to the coordinate system in Fig. 2 and Fig. 3 established. In addition, the respective end portion 118 is also in the z-direction by a wire having an outer structure, such as a knurling (not shown here) or another suitable joining method on the coordinate system in Fig. 2 and Fig. 3 or set in profile direction, so that in each case a shear-resistant connection is formed.

The insulating webs 114, 115 also have here on their side facing away from the respective end portion 118 each a Kederwulst 123 and a Kederfahne 124. Here, the second metallic outer profile 102 in each case has a groove 125 with a corresponding cross-sectional geometry, so that the respective Kederwulst 123 engages in the respective groove 125 and the respective Kederfahne 124 is led out of the groove 125. In this way, a sliding guide is formed. The shear strength in the sliding guide orthogonal to the cross-sectional plane of the composite profile may, but need not go to zero. Such a sliding guide is colloquially referred to as a "push-soft connection". Alternatively, the metallic center profile 103 may form the groove 125.

In a further alternative embodiment variant, the insulating webs 114 and 115 may also each have a Kederwulst 123 and a Kederfahne 124 at its two ends. Accordingly, in this case, both the metallic center profile 103 and the second metal outer profile 102 respectively form the groove 125.

In a further alternative embodiment variant, the insulating webs 114 and 115 also in each case a Kederwulst 123 and a Kederfahne 124 bez. have a groove 125 so that each Isoliersteg 114, 115 each result in two Isolierstegabschnitte, each one Isolierstegabschnitt the Kederwulst 123 and the Kederfahne 124 and the other Isolierstegabschnitt the groove 125 has. In the case, the Isolierstegabschnitte each have an end portion 118 and the respective metal profiles 102, 103 on a respective end portion 118 corresponding groove 119

The insulating web 115 has a groove 120 with an undercut, wherein the groove 120 is designed here as a groove with a T-shaped cross-section. In the groove 120 here is a cover plate 126 is positioned and fixed, which has a with the groove 120 geometrically corresponding, integrally formed on the cover plate 126 foot 127 which engages in the groove 120 and is snapped into the groove 120. The geometric Design of the undercut of the groove 120 may also be performed differently than T-shaped.

The shear strength of the sliding guide is chosen such that a displacement of at least two elements in the Isolierstegzone relative to each other due to dilation is possible without causing a tilting of the sliding guide and thereby adjusts a bending of the sash composite profile 100.

This results in a wing frame composite profile 100, the temperature-induced deformations by a shear soft or unobstructed connection of one of the metal profiles 101, 102, 103 and the respective insulating webs 114, 115 can compensate.

The second metallic outer profile 102 has, on its side facing away from the second insulating land zone II, two in each case with respect to the coordinate system in FIG Fig. 2 and Fig. 3 in the x-direction extending webs 128, 129 with free end. The two webs 128, 129 each have at their ends a groove 130 or 131 with an undercut for receiving a sealing profile 132 or another wing component - in this case the grip profile 300 or a grip profile 302 - on. The groove 130 or 131 has here in each case a T-shaped cross-section, alternatively, the groove 130 or 131 may also have another suitable cross-sectional geometry to realize an undercut.

The second metallic outer profile 102 and the metallic center profile 103 may also have an opening for a profile lock cylinder (not shown here).

The metallic outer profiles 101, 102 and the metallic center profile 103 are preferably produced as extruded aluminum profiles. Alternatively, the production is also possible from a different material such as steel and / or another manufacturing method. The insulating webs 106, 107, 114, 115 are made of a plastic material, such as polyamides (PA66, PA6, PPA), polyester (PET, PBT), polyolefins (PP) or polyvinyl chloride (PVC), so that each one extensive thermal Separation between the metal profiles 101, 102, 103 is achieved.

The frame composite profile 200 has a similar or similar structure as the sash composite profile 100. Therefore, in order to avoid repetition, only deviations and additions to the wing frame composite profile 100 will be described below.

The frame composite profile 200 (see Fig. 2 and Fig. 4 ) also has two insulating land zones III, IV. Notwithstanding the insulating webs 106, 107 of the first insulating land zone I of the sash composite profile 100, the window frame composite profile 200 in the first insulating land zone III insulating webs 206, 207, which are arranged vertically offset from one another.

The first metallic outer profile 201 of the frame composite profile 200 has on its side facing away from the first insulating land zone II a with respect to the coordinate system in Fig. 2 and Fig. 4 in the x-direction extending ridge 233. The web 233 has at its end a groove 234 with an undercut for receiving a sealing profile 221. The groove 234 here has a T-shaped cross-section, alternatively, the groove 234 may also have another suitable cross-sectional geometry to realize an undercut.

The insulating web 207 has a groove 220 with an undercut, wherein the groove 220 is designed here as a groove with T-shaped cross-section. In the groove 220, the sealing profile 221 is positioned and fixed, which has a with the groove 220 geometrically corresponding, integrally formed on the sealing profile 221 foot 222 which engages in the groove 220 and snapped into the groove. The geometric design of the undercut of the groove 220 may also be performed differently than T-shaped.

In Fig. 2 It is shown that the sealing profiles 121, 132, 221 seal a rebate space 400 against the environment formed between the frame composite profile 200 and the wing frame composite profile 100 in the closed state of the door 1. The sealing profiles 121 and 221 are in an operative connection, while the sealing profile 132 is in operative connection with the second metallic outer profile 202 of the frame composite profile 200. In addition, the sealing profile 221 is also with the first metallic outer profile 101 of the sash composite profile 100 in operative connection, so that the sealing profile 221 has two sealing levels.
In Fig. 2 and Fig. 4 It is shown that the metallic center profile 203 of the frame composite profile 200 different from the metallic center profile 103 of the sash composite profile 100 on only one side, one in the x direction (see coordinate system in Fig. 2 and Fig. 4 ) aligned groove 209 having an undercut, wherein the groove 209 is designed here as a groove with T-shaped cross-section. In the groove 209 here a cover plate 211 is positioned and fixed, which has a with the groove 209 geometrically corresponding, integrally formed on the cover plate 211 foot 212 which engages in the groove 209 and is snapped into the groove 209. The geometric design of the undercut of the groove 209 may also be designed differently than T-shaped.

The frame composite profile 200 has insulating ribs 206, 207 in its second insulating strip zone IV. The two insulating webs 206, 207 of the second insulating land zone IV each have at their two ends a thickened end portion 218. In this case, each of the end sections 218 preferably engages in a corresponding groove 219, which here is formed by a respective one of the metal profiles 202, 203. The respective end portion 218 preferably has a trapezoidal or triangular or wedge-shaped or L-shaped or rectangular cross section. The respective groove 219 accordingly has a cross section with a corresponding cross section. Accordingly, the insulating webs 206, 207, unlike the insulating webs 114, 115 of the second insulating web zone II of the sash composite profile 100, do not slide with the second metal outer profile 202 of the window frame composite profile 200 or the metallic center profile 203 of the window frame composite profile 200.

The two insulating webs 206, 207 of the second insulating land zone IV of the frame composite profile 200 are here slightly offset from one another vertically. Alternatively, it is also possible that the insulating webs 206, 207 are each offset horizontally from one another or arranged in a plane. Likewise, a diagonal orientation of the insulating webs 206, 207 is possible.

The handle profile 300 (see Fig. 2 and 5 ) is designed in a particularly advantageous manner as a heat-insulating composite profile that has the same width B as the wing frame composite profile 100 (see Fig. 2 ). The grip profile 300 accordingly has a metallic outer profile 301, in which at least one hollow chamber 304 is formed here, and a metallic grip profile 302, in which also preferably at least one hollow chamber 313 is formed.

The metallic outer profile 301 has a groove 308 into which, e.g. a glass retaining strip (not shown here) can be used. This functionality is used when the filling 11 of the wing 12 is e.g. a glazing (not shown here) is provided. The hollow chamber 313 of the metallic recessed grip profile 302 can be designed so that it can receive a lock case (not shown here). This makes it possible to produce a vertical wing frame spar 4 alternatively from a handle profile 300.

The metallic outer profile 301 is connected to the metallic recessed grip profile 302 via at least one or more first insulating webs (aligned parallel here) 306. These insulating webs 306 between the first metallic outer profile 301 and the metallic recessed grip profile 302 form a Isolierstegzone V or - level. Through the hollow chambers 304 and 313 results in each case a metal profile 301, 302 with a relatively high surface moment 2nd Order or area moment of inertia. Alternatively, the grip profile may also have two insulating web zones or planes, in which case the insulating web zone V is adjoined by a further metal profile which is connected to the recessed grip profile 302 via a second insulating web zone or plane.

The metallic outer profile 301 and the recessed grip profile 302 are preferably produced as extruded aluminum profiles. Alternatively, the production is also possible from a different material such as steel and / or another manufacturing method. The insulating webs 306 are made of a plastic material, such as polyamides (PA66, PA6, PPA), polyester (PET, PBT), polyolefins (PP) or polyvinyl chloride (PVC), so that in each case a substantial thermal separation between the metal profiles 301 and 302 is reached.

The metallic grip profile 302 has on its wing frame composite profile 100 side facing in the x direction (see coordinate system in Fig. 2 and Fig. 5 ), a web 335 which engages in the groove 110 with undercut of the metallic center profile 103 of the sash composite profile 100 and is defined by the undercut of the groove 110 in the groove 110. Thus, the recessed grip profile 302 or the grip profile 300 in the x-direction and in the y-direction (see coordinate system in FIG Fig. 2 and Fig. 5 ) fixed positively. The metallic grip profile 302 also has on its side facing away from the wing frame composite profile 100, which in the x direction (see coordinate system in Fig. 2 and Fig. 5 ), a groove 310 with undercut on.

The metallic grip profile 302 also has a recessed grip 336. The recessed grip 336 has on its side facing the hollow chamber 313 an arcuately shaped profile web 337. The arc of arc-shaped profile land 337 may be a circular arc or a portion of another curve, such as a curve. to be a section of a function graph. The recessed grip 336 is open to the outside A of the wing 12 of the door 1, so that the arcuately shaped profile web 337 limits the recessed grip 336 in the direction of the inside of the wing 12 or the door 1. In the arcuately shaped profile web 337 may also have an opening for receiving a profile closing cylinder (not shown here).

The recessed grip 336 also has an undercut, which is realized by an angled profile web 338. The angled profile web 338 has at its free end 339 a T-shaped cross-sectional geometry. The T-shaped cross-sectional geometry of the free end 339 engages in the undercut groove 130 with corresponding cross-sectional geometry, which forms the second metallic outer profile 102 of the wing frame composite profile 100. Thus, the recessed grip profile 302 or the grip profile 300 in the x-direction and in the y-direction (see coordinate system in FIG Fig. 2 and Fig. 5 ) fixed positively.

By this form-fitting determinations and a floating bearing that by a web 140, the first metallic outer profile 100 of the sash composite profile 100 in the region of the groove 108 and by the region of the metallic outer profile 301 of the handle profile 300, which faces the sash composite profile 100 is formed, the handle profile 300 is advantageously mounted or mounted on the vertical sash profile rail spar 4 and the sash composite profile 100.
This results in a particularly advantageous, rigid connection between the sash composite profile 100 and the sash frame member 4 formed therefrom and the handle profile 300, which act on the actuation forces or actuating moments acting on the handle profile 300 and on the door 1 and the resulting elastic deformations permanently endure without damage.

In addition, the handle profile 300 may be formed over the metallic center profile 103 of the sash composite profile 100 by fasteners, such as e.g. Screws are additionally fastened (not shown here).

In order to improve the operating comfort of the handle profile 300, the grip profile 300 at the bottom of its recessed grip 336 can have one or more light sources, such as e.g. have one or more LEDs (not shown here). As a result, the recessed grip 336 and thus at least partially the profiled cylinder can be illuminated in an advantageous manner at night, so that no additional illumination of the door 1 or an entrance area is required to open the door 1 with a key.

The recessed grip profile 302 also has - analogous to the second metallic outer profile 102 of the sash composite profile 100- on its side facing away from the Isolierstegzone V side, a with respect to the coordinate system in Fig. 2 and Fig. 5 in the x-direction extending web 328 with a free end. The web 328 has at its end a groove 330 with an undercut for receiving a sealing profile with which, for example, a folding region of a glazing is sealed when a glazing is provided for the filling 11 of the wing 12. The groove 330 here has a T-shaped cross-section, alternatively, the groove 330 may also have another suitable cross-sectional geometry in order to realize an undercut.

The web 328 with free end covers the edge of the filling 11, for example, a sandwich panel with a heat-insulating core made of foamed plastic. The grooves 310 and 330 and a groove 308, which is arranged analogously to the groove 108 of the first metallic outer profile 101 in the metallic outer profile 301 of the handle profile 300, in each case form undercuts that each form-fit connections with the filling 11, provided that the filling 11 is selected as a sandwich panel with a heat-insulating core made of foamed plastic.

The handle profile 300 thus has the same topology on its side facing the filling 12, as the sash composite profile 100, so that the connection topology or geometry of the filling 12 always remains the same, regardless of whether the filling 12 with the sash composite profile 100 or with the Handle profile 300 is connected.

In Fig. 6 an embodiment of the invention is shown. To avoid repetition, therefore, only deviations and additions to the embodiment of the invention will be described below.

Notwithstanding the in Fig. 1 illustrated variant of the invention, the door 1a after Fig. 4 two additional spars 13, 14, each spaced from each other parallel to the upper horizontal wing frame spar 6 of the door 1a are arranged so that the filling of the door 1a in several, here three filling zones 11a, 11b, 11c is divided. In other words, the filling zones 11a, 11b, 11c are separated from the bars 14, 15.

Here, the three filling zones 11a, 11b, 11c of the door 1a are made approximately the same width, here by the term "wide" or "width" is meant an extension parallel to the vertical sash 4.5 of the door 1. Alternatively, one or two or all filling zone (s) 11a, 11b, 11c may each have different widths.

Only one, here the middle of the filling zones 11a, 11b, 11c -here the filling zone 11b- has a handle profile 300. The handle profile 300 is here parallel to the vertical sash bars 4, 5 of the door 1 and has a length which is identical to the dimension of the filling 11b in its vertical extension direction or with its width.

This results in a particularly advantageous, particularly rigid connection between the wing frame composite profile 100 and the wing frame rail 4 formed therefrom, as well as the two bars 13, 14, which act on the actuating forces or actuating moments acting on the handle profile 300 and on the door 1 and The resulting elastic deformations can endure permanently without damage.

Alternatively, the handle profile 300 may also be arranged parallel to one of the spars 13, 14 or parallel to the horizontal sash spar 6, wherein the spars 13, 14 may also be arranged diagonally in the sash 2.

LIST OF REFERENCE NUMBERS

1

door

2

casement

3

frame

4

Leaf frame spar

5

Leaf frame spar

6

Leaf frame spar

7

Leaf frame spar

8th

Frame spar

9

Frame spar

10

Frame spar

11

filling

12

wing

13

Holm

14

Holm

100

Casement composite profile

101

outer profile

102

outer profile

103

agent profile

104

hollow

105

hollow

106

Insulating web

107

Insulating web

108

groove

109

groove

110

groove

111

cover

112

foot

113

hollow

114

Insulating web

115

Insulating web

116

hollow

117

hollow

118

end

119

groove

120

groove

121

weatherstrip

122

foot

123

Kederwulst

124

Kederfahne

125

groove

126

cover

127

foot

128

web

129

web

130

groove

131

groove

132

weatherstrip

140

web

200

Frame composite profile

201

outer profile

202

outer profile

203

agent profile

204

hollow

205

hollow

206

Insulating web

207

Insulating web

208

groove

209

groove

211

cover

212

foot

213

hollow

216

hollow

217

hollow

218

end

219

groove

220

groove

221

weatherstrip

222

foot

233

web

234

groove

300

handle profile

301

outer profile

302

Recessed grip profile

304

hollow

306

Insulating web

310

groove

313

hollow

316

hollow

318

end

319

groove

328

web

330

groove

335

web

336

grip

337

profile web

338

profile web

339

free end

400

rebate

I

Isolierstegebene

II

Isolierstegebene

III

Isolierstegebene

IV

Isolierstegebene

V

Isolierstegebene

A

outside

B

width

Claims (16)

1. A door (1) or a window comprising

   a. a sash (2) and

   b. a frame (3),

   c. wherein the sash (2) has sash spars (4, 5, 6, 7),

   d. wherein the sash spars (4, 5, 6, 7), together with a filling (11), form a casement (12) and

   e. the casement (12) furthermore has at least one handle profile (300),

   f. wherein the handle profile (300) is preferably arranged in parallel to one of the sash spars (4, 5, 6, 7),

   g. wherein the handle profile (300) is fixed on a sash composite profile (100),
   characterized in that

   h. the handle profile (300) has a handle groove (336), which is open toward the outer side (A) of the casement (12) of the door (1).
2. The door (1) or window according to Claim 1, characterized in that the handle profile has a handle groove profile (302), which has a hollow chamber (313).
3. The door (1) or window according to Claim 2, characterized in that the handle groove profile (302) is a metallic handle groove profile.
4. The door (1) or window according to Claim 1, 2, or 3, characterized in that the handle profile (300) has a metallic outer profile (301).
5. The door (1) or window according to Claim 2, 3, or 4, characterized in that at least one hollow chamber (304) is formed in the metallic outer profile (301).
6. The door (1) or window according to any one of the preceding claims, characterized in that the metallic handle groove profile (302) has, on its side facing toward the sash composite profile (100), a bar (335), which engages in a groove (110) having undercut of the metallic middle profile (103) of the sash composite profile (100) and is fixed in the groove (110) by the undercut of the groove (110).
7. The door (1) or window according to any one of the preceding claims, characterized in that the metallic handle groove profile (302) has, on its side facing toward the sash composite profile (100), an angled profile bar (338), which has a T-shaped cross-sectional geometry on its free end (339), wherein the T-shaped cross-sectional geometry of the free end (339) engages in an undercut groove (130), which forms the second metallic external profile (102) of the sash composite profile (100).
8. The door (1) or window according to any one of the preceding claims, characterized in that a floating bearing is formed by a bar (140), which the first metallic profile (101) of the sash composite profile (100) has in the region of a groove (108), and by the region of the metallic external profile (301) of the handle profile (300) which faces toward the sash composite profile (100).
9. The door (1) or window according to any one of the preceding claims, characterized in that the handle profile (300) has a compatible or identical topology on its side facing toward the filling to that on the adjoining sash composite profile (100) on its side facing toward the filling.
10. The door (1) or window according to any one of the preceding claims, characterized in that the second metallic external profile (102) of the sash composite profile (100) has, on its side facing away from the second insulating bar plane (II), one or two bars (128, 129) having free ends, wherein the bar or the two bars (128, 129) each have, on the end face, a groove (130) or (131), respectively, having an undercut.
11. The door (1) or window according to any one of the preceding claims, characterized in that the handle groove profile (302) has, on its side facing away from the insulating bar plane (V), similarly to the second metallic external profile (102) of the sash composite profile (100), a bar (328) having a free end, wherein the bar (328) has, on the end face, a groove (330) having an undercut, wherein preferably the grooves (310) and (330) and a groove (308), which is arranged similarly to a groove (108) of the first metallic external profile (101) of the sash composite profile (100) in the metallic external profile (301) of the handle profile (300), each form undercuts, in which the filling (12) engages.
12. The door (1) or window according to any one of the preceding claims, characterized in that the handle profile (300) has the same width (B) as the sash composite profile (100), from which the sash spars (4, 5, 6, 7) of the sash (12) are constructed.
13. The door (1) or window according to any one of the preceding claims, characterized in that the filling (11) has multiple filling zones (11a, 11b, 11c), wherein preferably the filling zones (11a, 11b, 11c) are separated from one another by spars (13, 14), wherein preferably only one of the filling zones (11a, 11b, 11c) has a handle profile (300).
14. The door (1) or window according to any one of the preceding claims, characterized in that the handle profile (300) is designed as a thermally-insulated composite profile, and/or the handle profile (300) is arranged in parallel to at least one or preferably two vertically aligned sash spar(s) (4, 5).
15. The door (1) or window according to any one of the preceding claims, characterized in that the handle profile (300) has at least one insulating bar plane (V), wherein the at least one insulating bar plane (V) of the handle profile (300) is formed by at least one or more insulating bars (306), by which a metallic external profile (301) is connected to a metallic handle groove profile (302), wherein preferably the handle profile (300) has a further insulating bar plane, wherein this insulating bar plane of the handle profile (300) is preferably formed by one or more further insulating bars (306), by which a further metal profile is connected to the metallic handle groove profile (302).
16. The door (1) or window according to any one of the preceding claims, characterized in that the sash composite profile (100) has at least one insulating bar plane (I, II), and preferably this at least one insulating bar plane (I) of the sash composite profile (100) is formed by insulating bars (106, 107), by which a first metallic external profile (101) is connected to a metallic middle profile (103), wherein a second insulating bar plane (II) of the sash composite profile (100) is formed by insulating bars (114, 115), by which the metallic middle profile (103) is connected to a second metallic external profile (102).

Images