EP3187677B1 - Method for producing a battery french casement window - Google Patents

Description

The invention relates to a method for producing a sash window or a sculpture door. The profile system used for this purpose comprises at least a frame profile, a sash profile, a faceplate base profile and a faceplate profile, the faceplate basic profile and the faceplate profile are connected to one another in a form-fitting manner.

Technical field

French sash windows or sash windows or doors are windows or doors with at least two sashes without a vertical post between the sashes. The wing that is to be opened first, also called the active wing or opening wing, strikes the other wing when it closes with an internal flap, usually called the left wing, ventilation wing, sash or passive wing. To the extent that in the following and in the claims the terms French window or french window are used in a simplified manner, this also means sculpture doors or french doors.

Plastic French sash windows are usually made from standard hollow chamber profiles. In the case of at least one of the sashes, the inner flap which is disturbing in the faceplate area and which serves as a stop on the frame in the areas outside the faceplate area must then be removed. This is associated with additional effort. In addition, the grooves or burrs that occur when the profile stop chamber is removed must be carefully removed and / or covered with a cover profile. Solutions with special faceplate base profiles are therefore already known.

State of the art

From the DE 101 55 475 A1 a profile system for producing a sash window is known in which, in addition to a standard casement profile, a sash base profile and a sash profile be used. The face plate profile is connected to the base profile with a positive fit, a screw connection of both profiles is also required. Due to the use of different sash frame and faceplate basic profiles in cross-section, this construction in the mitred composite area requires elaborate trimming and special sealing caps. Overall, the assembly effort is considerable.

The GB 2 166 792 A discloses a modular profile system for the production of different types of frames, comprising a basic profile with a simple rectangular cross-section and a number of different additional profiles which have to be connected to the basic profile in a latching manner and possibly by additional gluing and can be used in combination with the basic profile, for example as a sash profile or post profile , A step-wing variant is not mentioned. The effort for the production of windows from such profile systems is much higher than with conventional profile systems, so that such modular systems could not prevail in practice.

task

The object of the present invention is to provide a less complex method for producing a French window or a sculpture door.

Presentation of the invention

The invention solves this problem by a method according to claim 1, preferably in conjunction with one or more of the features of claims 2 and / or 3.

The profile system used in accordance with the invention comprises, in addition to a window frame profile and a casement profile, a faceplate base profile and a faceplate profile, the faceplate basic profile and the faceplate profile can be positively connected to one another. The faceplate basic profile and the faceplate blow profile have the means for positive connection each have a hook-shaped cam that is operatively connected to one another in the connected state and has an undercut and together a pair of latching connection means that are operatively connected to one another in the connected state. The hook-shaped cams and the locking connection means are arranged spaced apart from one another, a cavity for receiving adhesive being formed in the region between the hook-shaped cams and the locking connection means.

The frame profile, casement profile, faceplate base profile and faceplate blow profile are preferably produced as hollow chamber profiles made of PVC-U in the extrusion process.

According to the method according to the invention, three sash frame profiles and a faceplate base profile are first cut to miter and welded to one another in the miter area to form a protrusion in the upper and lower faceplate area to produce the fixed leaf. The excess is removed by machining, in particular by milling or by suitable saw cuts. The open end face area of the casement profile resulting from the machining can preferably be closed by means of a cover cap.

In the area between the hook-shaped cams and the locking connection means, adhesive is applied to the faceplate base profile and / or the faceplate blow molding profile and the faceplate blow molding profile is connected to the faceplate base profile by means of a rotary movement, the adhesive being pressed into the cavity and this at least partially fills.

The face plate profile according to the invention and the base plate face plate are therefore connected to each other both by gluing and by a form-fitting mechanical fastening. This leads to a high mechanical stability as well as to a reliable sealing of the two Profiles with each other and is also extremely efficient to assemble.

The faceplate base profile and the faceplate blow profile are locked together by means of a rotary movement.

The profile system according to the invention preferably has a cuff cap for closing the open ends of the face plate profile and a cover cap for closing the open end face region of the casement profile.

According to a particularly preferred embodiment of the invention, the faceplate base profile and the sash profile have a largely identical cross-sectional area. This ensures that when these profiles are welded in the miter area, the majority of the respective cross-sectional areas are welded together and excellent corner strength is achieved. The proportion of the welded area is preferably more than 75%, particularly preferably more than 85%, of the cross-sectional area of the faceplate base profile.

The method according to the invention enables the rational production of both stop and center seal systems with very narrow face widths and high corner strengths.

Brief description of the drawing

Fig. 1

eine Innenansicht eines erfindungsgemäßen Stulpfensters;

Fig. 2

die entsprechende Außenansicht des Stulpfensters gemäß Fig. 1;

Fig. 3

einen Horizontalschnitt durch das Stulpfenster gemäß Fig. 1 und 2;

Fig. 4

eine perspektivische Innenansicht des oberen Eckbereichs des Standflügels nach dem Verschweißen im Gehrungsbereich;

Fig. 5

eine perspektivische Innenansicht des oberen Eckbereichs des Standflügels nach dem Fräsen des Überstandes;

Fig. 6

eine perspektivische Innenansicht des oberen Eckbereichs des Standflügels nach dem Aufsetzen der Abdeckkappe;

Fig. 7

einen Schnitt durch das Stulp-Grundprofil;

Fig. 8

einen Schnitt durch das Stulp-Grundprofil und das Stulp-Schlagleistenprofil nach dem Verbinden;

Fig. 9

drei Schnitte in verschiedenen Phasen durch das Stulp-Grundprofil und das Stulp-Schlagleistenprofil beim Verbinden;

Fig. 10

eine perspektivische Ansicht des Stulp-Schlagleistenprofils mit Stulpendkappen;

The invention is explained in more detail below using an exemplary embodiment and the drawing. It shows:

Fig. 1

an interior view of a sash window according to the invention;

Fig. 2

the corresponding external view of the sash window according to Fig. 1 ;

Fig. 3

a horizontal section through the French window 1 and 2 ;

Fig. 4

a perspective interior view of the upper corner area of the passive leaf after welding in the miter area;

Fig. 5

a perspective interior view of the upper corner area of the passive leaf after milling the overhang;

Fig. 6

a perspective interior view of the upper corner area of the passive leaf after the cap has been put on;

Fig. 7

a section through the faceplate basic profile;

Fig. 8

a section through the faceplate base profile and the faceplate blow profile after connecting;

Fig. 9

three cuts in different phases through the faceplate base profile and the faceplate profile when connecting;

Fig. 10

a perspective view of the faceplate blow profile with cuff caps;

Best way to carry out the invention

The sash window 1 shown in the drawing and the explanation below essentially consists of the frame made of frame profiles 2 and two sashes, the one in FIG 1 and 3 left faceplate or passive leaf as well as in 1 and 3 the active or opening wing shown on the right. The handle 13 ( Fig. 3 ) is used to open the active or opening sash. All profiles used in this exemplary embodiment have been produced as hollow chamber profiles made of PVC-U in the extrusion process. The sash window 1 shown in this exemplary embodiment has three sealing levels as the central sealing system with the central seal 11, 12, an outer stop seal and the inner stop seal 10.

The average ( Fig. 3 ) The active or opening sash shown on the right consists of four identical standard sash frame profiles 3 welded together in the miter area and has - as usual - a reinforcement chamber with inserted steel reinforcement 15 and internal glass strips 16 which hold the glazing 14 together with the outer rollovers 8 , The standard casement profiles 3 have a very low overall height, so that the sash window 1 is extremely narrow View widths shows. The active or opening sash has an inner sash flap 29 on all four sides which, when the sash is closed, bears against the window frame or the abutment surface 34 of the faceplate 4 with an inner stop seal.

The in Fig. 3 In contrast to the opening sash, the inactive leaf shown on the left is welded together from three standard sash profiles 3 and the faceplate base profile 4. For this purpose, the faceplate base profile 4 and the sash frame profiles 3 are mitred and - in the faceplate area above and below, forming a protrusion 26 ( Fig. 4 ) - welded together. The passive leaf only points to the in Fig. 3 on the left side and above and below an inner wing flap 29 which, when the wing is closed, bears against the window frame via an inner stop seal 10, but this stop on the window frame is missing in the faceplate area.

The protrusions 26 in the upper and lower faceplate area are formed from the open miter ends of the inner wing overlap chambers 29 of the upper and lower horizontal wing frame profiles 3, since this inner wing overlap 29 is missing in the faceplate base profile 4.

With the exception of the wing rollover chamber 29 and the immediately adjacent area between the fitting groove 27 and the inside visible surface as well as the hook-shaped cam 18 and the locking web 19, the cross-sectional areas of the faceplate base profile 4 and the wing frame profile 3 are largely identical, so that when these profiles are welded, they are in the mitred area the majority of the cross-sectional area is also welded together. In this way, a high corner strength is achieved despite the narrow face width of the profiles.

After welding, the protrusions 26 are removed by machining, in particular by milling or corresponding saw cuts. The open resulting from the milling 21 End face regions 33 are then closed by covering 7. In the 5 and 6 is the upper cap 7 of the in Fig. 3 left wing shown. The lower cover cap, not shown in the figures, has the same shape, but in a mirrored design.

In Fig. 7 the faceplate basic profile 4 is shown in cross section. The outside is on the left, the inside on the right. The outer rollover 8 'corresponds in shape and function to the outer rollover 8 of the sash profile 3 and holds the glazing 14 together with the glazing bead 16 and the glazing seal 9, the sash rebate seal 17 thermally dividing the glazing rebate area into two areas in a manner known per se. The faceplate base profile 4 has the same cross section as the sash frame profile 3 over a wide range, in particular the steel chamber for receiving the steel reinforcement 15 and the fitting groove 27 are identical in shape and position. However, the faceplate basic profile 4 lacks the inner wing overlap 29 on the inside of the room, instead a web running parallel to the glazing 14 forms a stop surface 34 for the inner wing overlap 29 in FIG Fig. 3 pedestrian wing shown on the right. The hook-shaped cam 18 of the faceplate base profile 4 corresponds to the corresponding hook-shaped cam 22 of the faceplate blow bar profile 5, so that both cams 18 and 22 engage one behind the other during assembly. Likewise, the latching web 19 of the faceplate base profile 4 corresponds to the projection 32 of the faceplate blow bar profile 5. Together, this latching web 19 and the projection 32 form a latching connection.

The extending between the hook-shaped cam 22 and the projection 32 locking area of the face plate profile 5 corresponds in shape to the corresponding locking area 20 between the hook-shaped cam 18 and the locking bar 19 of the faceplate basic profile 4, these areas by the small cams 35 of the faceplate - Beat profile 5 to form the cavity 31 is kept at a short distance of a few tenths of a millimeter.

In the Fig. 7-9 the fastening of the face plate profile 5 to the already welded and milled passive leaf is shown. First, an adhesive bead made of commercially available PVC adhesive 24 is placed in the locking area 20 between the hook-shaped cam 18 and the locking bar 19 of the faceplate basic profile 4 ( Fig. 7 ) applied. The face plate profile 5 is then - as in Fig. 9 illustrated in three phases - connected in a form-locking manner by means of a rotary movement to the faceplate basic profile 4, the adhesive 24 largely filling the cavity 31. Due to the positive locking connection of the face plate 5 and faceplate 4, the adhesive 24 can harden or dry in peace without a screw connection being absolutely necessary. If required, however, the connection of the face plate profile 5 with the face plate base 4 - as in Fig. 8 shown - are additionally secured by one or more screws 25. The gluing of the faceplate base profile 4 to the faceplate blow bar profile 5 not only serves to permanently secure these two profiles, but also to seal them. An additional seal 23 seals the gap between the faceplate basic profile 4 and the faceplate profile 5 to the outside ( Fig. 9 ).

In Fig. 10 is symbolically shown how the cuff caps 6 close the upper and lower open ends of the face plate profile 5. The faceplate 6 has on its underside guide or clamping tongues which engage in the hollow chambers of the faceplate 5. In addition, the screws 28 connect the faceplate caps 6 to the faceplate profile 5.

Legend

1

Opening window

2

Frame profile

3

Casement profile

4

Stulp basic profile

5

Stulp impact strip profile

6

Stulpendkappe

7

Cover flap

8, 8 '

outer rollover (casement profile)

9

glazing gasket

10

inner stop seal

11

Center seal

12

Center seal forend profile

13

Handle

14

glazing

15

steel reinforcement

16

glazing bead

17

sash

18

hook-shaped cams

19

latching web

20

Rest area

21

milling

22

hook-shaped cams

23

poetry

24

adhesive

25

screw

26

Got over

27

fittings groove

28

screw

29

inner flap

30

deleted

31

Adhesive absorption cavity

32

head Start

33

open face area

34

stop surface

35

cam

Claims (3)

1. Method for producing a French casement window (1) or a French door using a profile system, comprising at least one outer frame profile (2), a casement or leaf frame profile (3), an astragal basic profile (4) and an astragal impact bar profile (5), wherein the astragal basic profile (4) and the astragal impact bar profile (5) have means for form-fitting connection to each other, wherein the astragal basic profile (4) and the astragal impact bar profile (5) as means for the form-fitting connection

   - each have a hook-shaped cam (18, 22), which cams are operatively connected to each other in the connected state and have an undercut, and

   - together have a pair of latching connection means (19, 32) which are operatively connected to each other in the connected state,

   - wherein the hook-shaped cams (18, 22) and the latching connecting means (19, 32) are arranged spaced apart from one another, and

   wherein a cavity (31) for receiving adhesive (24) is formed in the region between the hook-shaped cams (18, 22) and the latching connecting means (19, 32) in the connected state,
   characterized by the following method steps:

   - the astragal basic profile (4) and a casement or leaf frame profile (3) are cut to mitre and are welded to each other in the mitre joint region with an excess length (26) being formed;

   - the excess length (26) is removed by machining;

   - adhesive (24) is applied to the astragal basic profile (4) and/or to the astragal impact bar profile (5) in the region between the hook-shaped cams (18, 22) and the latching connecting means (19, 32);

   - the astragal impact bar profile (5) is connected in a latching manner to the astragal basic profile (4) by means of a rotational movement, wherein

   - the adhesive (24) at least partially fills the cavity (31).
2. Method according to Claim 1, characterized in that the open ends of the astragal impact bar profile (5) are closed by an astragal end cap (6) and the open end surface region (33) of the casement or leaf frame profile (3) is closed by a covering cap (7) .
3. Method according to either of Claims 1 and 2, characterized in that the astragal basic profile (4) and the casement or leaf frame profile (3) have a substantially corresponding cross-sectional area, and therefore, when said profiles are welded in the mitre joint region, the portion of the welded area is more than 75% of the cross-sectional area of the astragal basic profile (4).

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