EP3636869A1 - Multi-chamber hollow profile for fire safety doors or windows and method and device for producing such a multi-chamber hollow profile - Google Patents

Abstract

Shown and described is a multi-chamber hollow profile (1, 1 ', 1 ", 1"') for fire protection doors or windows with an outer hollow profile (2A, 2A ', 2A ", 2A'") and an inner hollow profile (2B, 2B ' , 2B ", 2B '"), the outer hollow profile (2A, 2A', 2A ", 2A" ') and the inner hollow profile (2B, 2B', 2B ", 2B" ') using at least two connecting webs (3, 3 "), which form at least one further hollow chamber (4) and the further / n hollow chamber (s) (4) are filled with a filler material (FM). In order to develop a fire protection profile system which consists of hollow profiles which are connected to one another by thermal separation, it is provided that a filler (6) which has both fire-retardant and heat-insulating properties is used as filler material (FM) in the further hollow chamber (s) (4) described, in which the filling material (FM) is mixed in the predetermined ratio and then by means of at least a lance (8) in the cavity of the respective further hollow body (s) (4) of the multi-chamber hollow profile (1, 1 ', 1 ", 1"') is filled, the lance (8) before filling to the end of Another hollow chamber / s (4) is introduced into this / n and is evenly pulled out of the hollow space of the hollow chamber / s (4) to be filled during the filling process.

Description

The invention relates to a multi-chamber hollow profile for fire protection doors or windows with an outer hollow profile and an inner hollow profile, the outer hollow profile and the inner hollow profile being connected by means of at least two connecting webs which form at least one further hollow chamber and the further / n hollow chamber / s with are filled with a filling material and a method and an apparatus for producing such a multi-chamber hollow profile.

A generic multi-chamber hollow profile is from the EP 0 802 300 A2 known. There is a framework of metal profiles in fire protection designs for windows, doors, facades or glass roofs is described. This known framework consists of an inner and an outer metal profile, each of which forms a hollow chamber profile. These two profiles are connected to each other via metal connecting bars, so that another hollow chamber is created. In the known multi-chamber hollow profile, the cavities are filled with energy-consuming and crystal water-releasing moldings which have to be introduced into the cavities as plates, rods or the like.

Also the EP 2 199 519 A1 and DE 34 38 861 A1 describe well-known multi-chamber hollow profiles with a similar topic. This is about hollow profiles that are connected by a thermal separation. At the same time, these hollow profiles form a further hollow chamber with the thermal separation. The thermal break is quickly destroyed in the event of a fire due to the materials used. This is particularly the case in DE 10 2005 059 633 B3 the approach is to permanently connect two hollow sections with additional mechanical connecting elements. For this purpose, a corresponding profiling of the hollow profiles suggested. However, all of the variants described have the disadvantage that they contain additional connecting elements, which can be a hindrance when machining the profile, and that they depend on the dimensions of the multi-chamber hollow profiles in terms of face width and structural depth. This inevitably leads to a high variant of the connecting elements and their area of application.

The above-mentioned documents also deal with solutions in which cooling, thermally insulating materials are used as a solid in the form of rods or cut-out plate strips in the hollow chambers. This also gives rise to the problem of a correspondingly high variant with different profile sizes. From the published application DE 32 24 001 A1 is already known to work with a mineral filler and an appropriate binder, not the solution with rods or plate strips. Here the mixture takes on both load-bearing and fire-insulating functions.

Fire protection doors have been used in outdoor applications for a number of years. The reason for this is the increasing density of installation space in cities. Buildings are moving closer together and a fire spreading from one building to another or to other parts of the building must be prevented. Due to this growing area of application for fire protection doors and windows, new performance requirements such as wind and driving rain protection as well as thermal protection also come up to the multi-chamber hollow profiles used.

The energetic heat protection differs significantly from the fire protection technology. While as little thermal energy as possible is to be lost through the door in the case of energetic heat protection, as much energy as possible through the door or its components is to be used in fire protection in order to withstand a fire for as long as possible. With thermally separated profiles in Fire protection is minimal, as in the case of the EP 0 802 300 A2 described multi-chamber hollow profiles. In addition to the rods or plate strips already described with temperature-resistant brackets or clamps (as in the DE 77 32 314 U1 ) a material with fire protection properties, in this case asbestos cement, with an appropriate strength can be used. Here, the first variant has the disadvantages described above and the second the disadvantage of the materials chosen, which generally have a very high density for the load-bearing capacity / strength with very poor thermal insulation.

The object on which the invention is based is to develop a fire protection profile system which consists of hollow profiles which are connected to one another by a thermal separation.

This object is first achieved in the case of a multi-chamber hollow profile of the type mentioned at the beginning and described in more detail above in that a filler which has both fire-retarding and heat-insulating fire properties is used as the filler material in the further hollow chamber / s.

These material-specific properties of the filler can be adjusted depending on the requirements, both with regard to their fire-retardant and also with regard to their heat-insulating properties. In order to facilitate processing, additional heat-resistant mechanical connecting elements have been dispensed with in the hollow chamber (s) formed between the hollow profiles and the connecting webs.

For the fire-retardant property, hydrophilic mineral fillers are already known that react with a blowing agent that releases gases through chemical or biochemical reactions and penetrates the filler. In addition, the filler combines with still air (bubbles) for thermal insulation. This reaction process is expediently triggered by water and also binds part of the liquid for fire retardancy.

A mixture of an inorganic mineral and water and hydrogen peroxide are used as blowing agents as filler. The percentage distribution of the individual parts is adapted to the respective requirements of the fire protection door / window. In this way, an optimal adaptation of the multi-chamber hollow profiles to be produced can be set individually for the respective purpose.

An automatically foaming and self-curing inorganic mineral foam as a filler is known per se and in the DE 10 2016 001 930 A1 described in more detail. The known mineral foam can be processed at ambient pressure and ambient temperature and is therefore particularly suitable as a filler for the multi-chamber hollow profile according to the invention.

In a further embodiment of the invention, the inner and the outer hollow profile consist of metal, preferably of aluminum. Aluminum offers sufficient stability and, in the event of a fire, meets the requirements of a sufficiently long stability.

A further teaching of the invention provides that the two hollow profiles have at least one anchoring web in the region of the further hollow chamber / s on their outside facing the respective other hollow profile. Through the appropriate design, the cavity to be filled is segmented and a larger area is created for the connection of the filling material.

In a preferred development of the invention, it is also expedient if the connecting webs have one or more anchoring webs. This also allows the area for the connection of the multi-chamber hollow profile to the filling material to be increased still further.

In a further preferred embodiment of the invention, the connecting webs consist of a thermoplastic, preferably polyamide (PA). Sufficient strength with good thermal insulation is thus achieved for the further hollow chambers that arise.

In a method according to the invention for producing a aforementioned multi-chamber hollow profile, the object is achieved in that the filling material is poured into the further hollow chamber (s) as a flowable mixture and cures there.

According to a further embodiment of the invention, the filling material is mixed in a predetermined ratio and then filled into the cavity of the respective further hollow chamber / s of the multi-chamber hollow profile by means of at least one lance, the lance being filled up to the end of the further hollow chamber / s before this / n is inserted and is evenly pulled out of the further hollow chamber / s to be filled during the filling process. This type of filling achieves reliable complete filling and an optimal distribution and uniform density of the filling material in the interior of the multi-chamber hollow profile according to the invention. The properties of the filler material can be adjusted according to the requirements, both with regard to their fire-retarding and also with regard to their heat-insulating properties, by means of a production-specific process control.

For this purpose, the flow rate of the mixture, the delivery rate when filling and the speed of the lance when pulling out of the multi-chamber hollow profile can be varied in order to adjust the physical and material-specific properties of the filling material to the respective intended use to be able to.

Finally, the object is achieved in a device for producing a multi-chamber hollow profile according to the invention in that a plurality of parallel arranged and prepared multi-chamber hollow profiles are clamped side by side and / or one above the other and arranged inclined to the horizontal and successively from an axially movable and perpendicular to their longitudinal axis in the direction of filling multi-chamber hollow profiles movable lance can be filled.

In addition to the movable lance, such a device according to the invention has a storage container for receiving the premixed filling material and at least one pump, by means of which the filling material and preferably a shut-off valve for filling the multi-chamber hollow profiles are conveyed into the lance. For this purpose, the lance can be moved in its axial direction and can be moved perpendicularly in order to move the cavities to be filled in and out into the multi-chamber hollow profiles clamped next to and / or one above the other for the filling process. The device according to the invention also includes designs with a plurality of lances.

Fig. 1A

ein erstes Ausführungsbeispiel eines erfindungsgemäßen Mehrkammerhohlprofils im Querschnitt,

Fig. 1B bis 1D

weitere Ausführungsbeispiele von erfindungsgemäßen Mehrkammerhohlprofilen im Querschnitt,

Fig. 2

das Mehrkammerhohlprofil aus Fig. 1A, wobei bei einem Brand von innen das innere Hohlprofil vollständig und ein Teil der Isolierstege abgeschmolzen ist,

Fig. 3

das Mehrkammerhohlprofil aus Fig. 1A, wobei bei einem Brand von außen das äußere Hohlprofil vollständig und ein Teil der Isolierstege abgeschmolzen ist und

Fig. 4

eine Vorrichtung zum Herstellen der erfindungsgemäßen Mehrkammerhohlprofile in schematischer Seitenansicht.

The invention is explained in more detail below with the aid of a drawing which represents only preferred exemplary embodiments. Show in the drawing

Fig. 1A

a first embodiment of a multi-chamber hollow profile according to the invention in cross section,

1B to 1D

further embodiments of multi-chamber hollow profiles according to the invention in cross section,

Fig. 2

the multi-chamber hollow profile Fig. 1A , in the event of a fire, the inner hollow profile is completely melted and part of the insulating webs have melted away,

Fig. 3

the multi-chamber hollow profile Fig. 1A , in the event of a fire the outer hollow profile is completely melted and part of the insulating webs and

Fig. 4

a device for producing the multi-chamber hollow profiles according to the invention in a schematic side view.

The Figures 1A to 1D show different multi-chamber hollow profiles. In Fig. 1A A multi-chamber hollow profile 1 for a fire door or a fire protection window is shown with an outer hollow profile 2A and an inner hollow profile 2B, the outer hollow profile 2A being connected to the inner hollow profile 2B via two connecting webs 3. In this way, a third hollow chamber 4 is formed, which is filled with a filling material, which is shown in FIG Fig. 1A is not shown. To increase the overall strength, both the outer hollow profile 2A and the inner hollow profile 2B have a plurality of anchoring webs 5 on the mutually facing outer sides, which form a positive connection with the hardened filler material (not shown). According to the invention, the filling material that is introduced into the hollow chamber 4 has both fire-retardant and heat-insulating properties.

As stated, the shape of the outer and inner hollow profiles 2A and 2B shown is selected at random and is not intended to limit the exemplary embodiment of the present invention to this. Any hollow profiles are conceivable as long as they can be connected to each other to form a multi-chamber hollow profile only by means of corresponding connecting webs.

The Figure 1B and 1C show further preferred embodiments, which are compared to Fig. 1A but only differentiate in the design of the anchoring webs. At Figure 1B the outer hollow profile 2A 'has only one anchoring web 5' centrally on the outside facing the inner hollow profile 2B ', the inner hollow profile 2B' also being symmetrical to the one already has said anchoring web 5 'arranged further anchoring web 5'. In 1C it is shown that the anchoring webs 5 "used there can also be laterally offset.

This in Figure 1D The multi-chamber hollow profile 1 '' shown essentially corresponds to the multi-chamber hollow profile 1 Fig. 1A . While the two outer and inner hollow profiles 2A '"and 2B'" in the exemplary embodiment shown have no anchoring webs, the modified connecting webs 3 "each have two corresponding inwardly anchoring webs 5"". The omission of the anchoring webs on the outer and inner hollow profiles 2A '"and 2B'" only serves to provide a better overview. Of course, the in Figure 1D connecting webs 3 "shown in the 1A to 1C Use embodiments shown.

Also, for the sake of better clarity in all 1A to 1D the filler is not shown.

In all of the variants shown, the filling of the hollow chamber 4 with filler as filler material should take place by means of a lance inserted into the hollow chamber 4 and described in more detail later, so that the anchoring webs 5, 5 ', 5 "used do not go too far into the interior of the respective one Hollow chamber 4 should protrude in order to allow a sufficient cross-section for receiving the lance and also a uniform filling of the hollow chamber 4.

In the event of a fire, a fire protection door or window must be able to withstand the temperatures that arise for as long as is required for the respective application (e.g. 30 or 60 minutes; fire protection classes EI 30, EI 60). The overall construction of the multi-chamber profile should remain sufficiently stable.

In Fig. 2 a case is shown in which a fire acts on the inner hollow profile 2B from the inside in the direction of the arrows 7. The inner hollow profile 2B melts and certainly also a region of the connecting webs 3, so that as in FIG Fig. 2 shown after melting, the outer hollow profile 2A and any residues 3 'of the partially melted connecting webs 3 are still preserved, the hardened filling 6 inside the further hollow profile 4 (cf. Fig. 1A ) is largely retained thanks to its fire-retardant and heat-insulating properties.

In Fig. 3 A corresponding case is shown in which the fire side acts on the multi-chamber hollow profile according to the invention from the outside, so that after the outer hollow profile 2A has melted, as in the right part of FIG Fig. 3 shown, only the inner hollow profile 2B, remnants of partially melted connecting webs 3 'and the hardened filler material 6 remain.

The cavity of the further hollow chamber 4 is filled by means of a lance 8, as schematically in FIG Fig. 4 , in which a device for producing a multi-chamber hollow profile according to the invention is shown schematically and shortened in side view, in which the lance 8 can be inserted into the hollow chamber 4 of the multi-chamber hollow profile 1. After the lance 8 has been introduced into the hollow chamber 4, the actual filling process begins, in which filler material FM is fed from a reservoir V by means of a pump P via lines 9 and 10 to the upper end of the lance 8. A shut-off valve 11 is expediently also present in this area, so that no filling material FM can escape when the lance 8 is inserted into the hollow chamber 4 of the multi-chamber hollow profile 1.

It is clear that the arrangement shown is only intended to show the filling principle, in practice a plurality of parallel multi-chamber hollow profiles 1 can be arranged side by side and / or one above the other and the lance must be approximately as long as the profiles to be filled and via corresponding ones The guide device can be moved axially on the one hand and can be moved mechanically perpendicular to its longitudinal axis in the direction of the multi-chamber hollow profiles 1 to be filled.

Claims (12)

Multi-chamber hollow profile (1, 1 ', 1 ", 1"') for fire protection doors or windows with an outer hollow profile (2A, 2A ', 2A ", 2A"') and an inner hollow profile (2B, 2B ', 2B ", 2B "'), the outer hollow profile (2A, 2A', 2A", 2A '") and the inner hollow profile (2B, 2B', 2B", 2B '") being connected by means of at least two connecting webs (3, 3") which form at least one further hollow chamber (4) and the further hollow chamber (s) (4) are filled with a filling material (FM),
characterized in that
a filler (6) which has both fire-retardant and heat-insulating properties is used as the filler material (FM) in the further hollow chamber (s) (4). Multi-chamber hollow profile (1, 1 ', 1 ", 1"') according to claim 1,
characterized in that
the outer and the inner hollow profile (2A, 2A ', 2A ", 2A"'; 2B, 2B ', 2B ", 2B'") consist of metal, preferably aluminum. Multi-chamber hollow profile (1, 1 ', 1 ", 1"') according to Claim 1 or 2,
characterized in that
the outer hollow profile (2A, 2A ', 2A ") on its outside facing the inner hollow profile (2B, 2B', 2B") at least one anchoring web (5, 5 ', 5 ") in the region of the further hollow chamber (s) (4) having. Multi-chamber hollow profile (1, 1 ', 1 ", 1"') according to one of Claims 1 to 3,
characterized in that
the inner hollow profile (2B, 2B ', 2B ") on its outside facing the outer hollow profile (2A, 2A', 2A") at least one anchoring web (5, 5 ', 5 ") in the region of the further hollow chamber (s) (4) having. Multi-chamber hollow profile (1, 1 ', 1 ", 1"') according to one of Claims 1 to 4,
characterized in that
the connecting webs (3 ") have one or more anchoring webs (5"'). Multi-chamber hollow profile (1, 1 ', 1 ", 1"') according to one of Claims 1 to 5,
characterized in that
the connecting webs (3, 3 ") consist of a thermoplastic. Multi-chamber hollow profile (1, 1 ', 1 ", 1"') according to Claim 6,
characterized in that
the connecting webs (3, 3 ") are made of polyamide (PA). Method for producing a multi-chamber hollow profile (1, 1 ', 1 ", 1"') according to one of Claims 1 to 7,
characterized in that
the filling material (FM) is poured into the further hollow chamber (s) (4) as a flowable mixture and cures there. A method according to claim 8,
characterized in that
the filling material (FM) is mixed in the predetermined ratio and then filled into the cavity of the respective further hollow body (s) (4) of the multi-chamber hollow profile (1, 1 ', 1 ", 1"') by means of at least one lance (8) , wherein the lance (8) is inserted into the hollow chamber (s) before it is filled and is evenly pulled out of the hollow chamber (s) (4) to be filled during the filling process. Method according to claim 9,
characterized in that
the flow rate of the mixture, the conveying capacity when filling and the speed of the lance (8), the conveying capacity when filling and the speed of the lance (8) when pulling out of the further hollow chamber (s) (4) can be varied to set the desired configuration of the filling material . Device for producing a multi-chamber hollow profile (1, 1 ', 1 ", 1"') according to one of Claims 1 to 7,
characterized in that
a plurality of prepared multi-chamber hollow profiles (1, 1 ', 1 ", 1"') are clamped side by side and arranged inclined to the horizontal and successively from an axially movable and perpendicular to their longitudinal axis in the direction of the multi-chamber hollow profiles (1, 1 ', 1 ", 1"') movable lance (8) can be filled. Device according to claim 11,
characterized in that
the device has, in addition to the movable lance (8), a storage container (V) for receiving the premixed filler material (FM) and at least one pump (P), by means of which the filler material (FM) via lines (9, 10) and preferably a shut-off valve ( 11) for filling the multi-chamber hollow profiles (1, 1 ', 1 ", 1"') is conveyed into the lance (8).

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