DE10356889A1 - Shared fire door installation - Google Patents

Abstract

Fire protection door comprises a fire protection insert divided into several separate partial sections with different fire-preventing properties. Preferred Features: The partial sections are divided into several layers in the direction of the thickness of the insert. The fire protection insert comprises a fire protection agent which shows an endothermic chemical and/or physical reaction, especially phase conversion and/or water splitting, during a temperature rise. The fire protection agent is made from a hydroxide, preferably aluminum or magnesium hydroxide.

Description

The The present invention relates to a fire door according to the preamble of Claim 1.

Fire doors are common from a shell Made of sheet steel with appropriate framework and arranged in the shell Fire protection insert built, with the fire protection insert next thermal insulation Fabrics such as mineral wool and especially rock wool also fire retardants characterized by the effect of heat in case of fire an endothermic chemical and / or physical reaction, such as phase transformations or the delivery of physical and / or cause chemically bound water, so that by the fire generated heat at least partially reduced by the corresponding reactions. Thereby is achieved that according to the standardized Fire resistance classes required service life can be achieved. For example, a fire door of the fire resistance class F30 a 30-minute To reach service life, wherein on the fire side of the door a predetermined Temperature, about 1000 ° C, on the door acts on the protected side within the service life the temperature over may rise to a certain limit. There is accordingly different standardized fire resistance classes like F30, F60 or F90, where the corresponding service lives are 30, 60 or 90 minutes must be.

Such fire doors are, such as in the DE 199 52 931 A1 described, either multi-layered with outer thermal barrier coatings and a preferably centrally arranged fire protection agent layer or even executed within the heat insulation evenly distributed or integrated in this fire protection. However, even in the latter case, a multi-layered construction with multiple layers in the thickness direction is often chosen, since at the required thicknesses of the fire protection inserts or the fire doors, the fire protection inserts in one piece achieve too high a weight and therefore complicate the production of fire doors. However, multi-layer door protection inserts increase the effort of introducing the fire protection insert into the shell of the fire door. The insert itself is always present in a plate shape according to the height of the cavity of the steel door to be filled.

outgoing from this prior art, it is an object of the present invention a fire door provide that is easy and inexpensive to produce and yet the requirements of fire protection in particular according to the specified Fire resistance classes is sufficient.

These Task is solved through a fire door with the features of claim 1. Advantageous embodiments are the subject of the dependent Claims.

According to the invention, the fire protection insert is made on the one hand in several parts, wherein at least one upper and one lower part or optionally also a plurality of superposed parts, ie layers, are provided and on the other hand, the parts are equipped with different fire retardancy. The fact that according to the invention not only a plate is used to fill the cavity of the steel sheet door, but at least two insulating elements, also facilitates handling during assembly of the fire door, since the difficult handling of large areas and thus fracture-susceptible plates of the fire protection insert is avoided. It should be noted that the production of fire doors usually not yet done mechanically, but the installation is done manually. This simplifies the manufacture of fire doors. Due to the invention made subdivision but also the individual part or insulating element can be designed specifically for the required fire protection properties. In this case, it has been recognized that as a rule the critical area is located in the upper area of the steel door, since the upper door seal in the frame on the transversely and bilaterally present steel sheet better transfers the temperature to the door leaf than, for example, in the central area of the fire door, where the frame rests only on both sides of the door leaf. Furthermore, with increasing heating, the insulating liner sags downwards, so that the density above becomes progressively lower and therefore high temperatures in the upper region on the side facing away from the fire can be measured after a short time. However, since the fire protection insert is to be designed for service life, in the prior art the Dämmeinlage is designed starting from the critical area, which means that when using a Feuerdämmplatte the plate must be designed in total with respect to the critical area. This inevitably results in a corresponding cost of materials, which also leads to an increase in the price of the fire door. The fact that according to the invention, however, the parts can be designed individually to the corresponding fire retardant properties, it is possible that the uppermost insulating element, ie the insulating element, which is located in the critical area, can be designed according to these criteria, whereas the lower Insulating elements on the other hand, lower fire protection resistance can be designed. Ie., in the upper part of the mineral wool insulation element is made with an increased density, whereas the Rohdichtebereich for the lower insulation elements can be reduced. As a result, oversizing at the bottom can be prevented, resulting in a total cost savings. This results in a fire door with the expected temperature loads specially adapted fire protection insert, which can be equipped so to speak, partially with the required fire retardant effect. This results in more substantial resource savings.

tries have also revealed that in particular the upper areas of a Fire door are exposed to a strong temperature load while the Lower areas experience lower temperature loads. So had For example, an attempt in which a fire door on the exposed to a side of a temperature of 1000 ° C, show that after a life of 100 minutes on the protected side the fire door Temperature differences of up to 100 K exist. Corresponding is it is advantageous in the less thermally stressed lower areas low fire retardant materials, ie in particular mineral fiber boards with appropriate fire retardants, to be provided as in the top door areas with high temperature load.

All in all Thus, it is advantageous to adapt the fire protection insert to the respective needs multipart in the build on a modular design, with a Subdivision of the fire protection insert not only in the transverse direction par excellence, but especially in the field of door locks may be useful. Of course they are also other divisions possible.

In Door lock height can in a built-up of a top and a bottom insert in the door lock area a middle layer may be provided, which in turn is in the width direction the door in two parts and in a door lock segment and a remaining segment may be subdivided so that for the door lock segment prefabricated standardized components can be used. Also this considerably simplifies the manufacture of fire doors.

Around to prevent along the bumps where the corresponding Collide parts of the fire protection insert, especially in the thickness direction a quick fire or heat transfer occur can, it is advantageous that the resulting between the parts At least formed in the thickness direction of the fire protection insert overlapping shock. This can be achieved by a centering connection of the adjacent ones Parts of the fire protection insert or a compound in the form of a Form fit done, for example, a shiplap or a Tongue / groove connection, possibly also with a cord or string-like Insert in the joint area the insulation elements.

Preferably become stronger fire-retardant parts in the upper part of the fire door in one Range of up to 25% to 40%, especially about 30% and 33% the total height the door provided, because normally the increased Temperature stress in this area occurs, especially in the upper third of the door.

In addition, additional Fire protection provided or integrated in the fire protection insert be, preferably a substance which in temperature increase or heat stress an endothermic chemical and / or physical reaction in particular in the form of a phase transformation and / or dehydration shows. Such substances are, for example, hydroxides, in particular metal hydroxides, wherein here preferably aluminum or magnesium hydroxide have proven. These substances can in the fire protection insert made of mineral wool and especially rock wool equally distributed be or in a separate location, for example, using of binders such as water glass, silica sol and / or magnesia binder be used. It can a plurality of corresponding fire protection layers may be provided, wherein However, it is proven has a single layer in the middle of the parts of the fire protection insert provided.

Further Advantages, characteristics and features of the present invention in the following detailed description of two embodiments with the attached Drawings clearly. The attached Drawings show in a purely schematic way in

1 a side view of a fire door according to the invention, in which the sheet steel shell has been omitted at the front;

2 a sectional view of the fire door 1 along the section line BB;

3 a sectional view of the fire door 1 along the section line AA; and in

4 a side view of another embodiment of a fire door according to the invention.

In 1 is a side view of a fire door 1 represented, the peripherally a Rah frame construction 2 which, together with steel sheet shells 3 and 4 (please refer 2 and 3 ) an outer shell of the fire door 1 forms. Inside the case are two parts 5 and 6 arranged a fire protection insert, wherein the upper part 5 extends over about 40% of the total length of the door, while the lower part 6 in the remaining area of about 60% of the total length. As in particular from the 2 and 3 it can be seen, is both the upper part 5 as well as the lower part 6 constructed in three layers, namely from a first rock wool layer 7 and a second rock wool layer 9 , which are arranged on the outsides, as well as a center between the rock wool layers 7 and 9 located fire protection layer 8th , The fire protection situation 8th may in this case consist of a dehydrating agent when exposed to heat, for example a dehydrating hydroxide such as aluminum hydroxide or magnesium hydroxide, which is mixed with binders such as water glass, silica sol and / or Magnesiabinder. Of course, the fire protection layer 8th Also include rock wool or mineral wool in general, in which the fire retardant, which exhibits an endothermic chemical and / or physical reaction in the case of heat, is stored or integrated.

In the embodiment shown, the upper part 5 as well as the lower part 6 each executed as a plate, but the individual layers, ie the first mineral wool layer 7 and the second mineral wool layer 9 as well as the fire protection layer 8th may also be designed as separate parts, in particular in plate form.

To the bumps of the parts, so in the illustrated embodiment of 3 at the push 10 between shell 5 and lower part 6 , a heat or fire spread along the push 10 To prevent this is designed so that in the thickness direction of the fire protection insert is given an overlap. Thus, the adjacent and abutting parts preferably have a shape such that they can be assembled into a positive connection or a centering connection, so that a butt overlap is achieved. In this case, in particular a stepped rebate or a tongue and groove connection has proven itself, as in 3 with the shiplap shown 11 the case is.

In the embodiment shown the 3 is also easy to see that by the clever arrangement of the fire protection layer 8th in the middle of the fire protection insert and the training of the shiplap at 11 with the shock course within the fire protection layer 8th ensures that along the push 10 no rapid heat or fire penetration is possible. Rather, it is due to the long course of the shock 10 in the fire protection layer 8th ensures a particularly high fire resistance.

The 4 shows a further embodiment of a fire door according to the invention 100 in which the perimeter framework 12 only shown schematically. The fire door 100 has a fire protection insert, the total of three parts 14 to 16 includes, wherein 13 a space is left for a later to be used lock case. While the top 15 and the lower part 16 with the shell 5 and the lower part 6 the previous embodiment of the 1 to 3 are comparable, is in the fire door 100 a middle layer between top 15 and lower part 16 with the segment 14 provided, which is shorter around the width of the lock case. This subdivision of the fire protection insert into a total of three parts 14 to 16 is advantageous if a lock or lock case in the area of the free space 13 should be provided. Through the provided free space 13 eliminates advantageous later processing of the door leaf to use a lock case can.

The by the subdivision of the fire protection insert of the fire door 100 formed seams 17 . 18 and 19 can be analogous to the seam 10 the embodiment of the 3 be formed.

Claims (12)

Fire-resistant door having a fire resistance characteristic according to standardized fire resistance classes, comprising a casing ( 2 . 3 . 4 ), in particular a comprehensive framework ( 2 ) and two-sided sheet steel shells ( 3 . 4 ) and a fire protection insert disposed in the shell with mineral fibers, in particular rock wool, which are soluble in particular in a physiological milieu, characterized in that the fire protection insert is subdivided transversely to its height-wise longitudinal extent into a plurality of separate sections with different fire-retardant properties. Fire door according to claim 1, characterized in that the subsections in each case in several layers ( 7 . 8th . 9 ) are divided in the direction of the thickness of the insert. Fire door according to claim 1 or 2, characterized in that the upper part ( 5 . 15 ) or the upper layers are designed to be more fire-retardant than the lower part or the lower layers of the fire protection insert. Fire door according to one of the preceding claims, characterized in that at least one partial section (segment 14 ) in the direction of the width of the fire protection insert for receiving ei lock box (open space 13 ) is formed shortened. Fire door according to one of the preceding claims, characterized in that the abutting parts of the fire protection insert are at least partially formed so that the resulting shocks between the parts ( 10 . 17 . 18 . 19 ) are performed overlapping in the thickness direction of the fire protection insert, in particular in on a centering connection or a positive connection, preferably a stepped rebate, a tongue / groove connection or the like. Fire door according to one of the preceding claims, characterized in that the parts alone or in combination, in particular the layers, at least partially as plates ( 5 . 6 ) are formed. Fire door according to one of the preceding claims, characterized that the fire protection insert comprises a fire retardant which at temperature rise an endothermic chemical and / or physical Reaction, in particular a phase transformation and / or dehydration shows. Fire door according to claim 7, characterized in that the fire retardant a hydroxide, in particular metal hydroxide, preferably aluminum or magnesium hydroxide. Fire door according to claim 8, characterized in that the fire protection insert consists of two sections, of which the upper section 55 to 75%, preferably about 60% and the lower section about 35 to 45%, preferably 40% of a dehydrating substance having. Fire door according to claim 8 or 9, characterized in that the fire protection agent in the center is arranged to the thickness of the fire protection insert. Fire door according to one of the preceding claims, characterized that raised to Fire retardant effect designed parts, especially the upper Part a higher one Contains fraction of fire retardant. Fire door according to one of the preceding claims, characterized that the two sections in their longitudinal extent in about the ratio top / bottom as 1: 3 are divided.