EP0133565A2 - Composite section - Google Patents

Abstract

The composite profile consists of concrete (6) and a profile (1) whose open chambers are largely filled with concrete, while the outer surfaces of the flanges of the profile have no concrete cover. At least one flat iron (2) connected to the web of the profile is arranged in the concrete. The flat bars can be arranged in the middle and continuously or also alongside one another.

Description

The invention relates to composite profiles, in particular supports, formed from concrete and at least one profile, the open chambers being largely filled with concrete and the outer surfaces of the flanges being exposed, i.e. are not covered with concrete. Such composite profiles are used in the construction of houses, halls, warehouses, etc. if fire resistance is to be achieved.

In the past it was common to measure the cross-sections of the profiles of a steel skeleton according to the static loads at room temperature and to meet the fire protection requirements that are always required in multi-storey buildings by subsequently covering the profiles in a costly manner. Recently, there has been a move to use fire-resistant composite profiles, which do not have to be clad. For example, DE-OS 28 29 864 describes a composite profile which, on the flange outer sides, i.e. has no concrete outside the profile outline. The chamber concrete is non-positively connected to the inside of the steel profile by welded compound in order to avoid detachment of the chamber concrete both at room temperature and at fire temperature. Steel profile cross-section, concrete cross-section and reinforcement steel cross-section contribute proportionately according to their surface area and their temperature-dependent strength. In the event of a fire, the temperature rises and the load is continuously shifted from the steel section to the reinforced concrete section, primarily due to the softening of the flanges, which make up the majority of the steel section.

Since the reinforcement in the concrete is not optimally arranged, what the In the event of a fire in the profile, the temperature distribution that arises has been proposed by the applicant in LU 84 772 to arrange at least one additional profile in the concrete, which is connected to the web of the main profile, the outer flanges of which are not covered with concrete. Since some of the profiles that make up this composite profile are installed in thermally protected zones, a high load-bearing capacity is guaranteed under fire. As a disadvantage, it can be stated here that this composite profile is of relatively complex construction and large external dimensions, the use of which is particularly suitable in high-rise buildings.

The invention has for its object to provide a composite profile of the type mentioned, which avoids the disadvantages mentioned above and is characterized by increased load-bearing capacity and fire resistance with approximately the same external dimensions. In addition, this composite profile should be characterized by a targeted height-dependent load capacity.

This object is achieved by the composite profile according to the invention, in which at least one flat iron is arranged in the concrete and is connected to the web of the profile.

The composite profiles according to the invention, which are constructed either from common hot-rolled profiles or from welded special profiles and from flat iron, have large masses of steel in the fire-protected area. The flat bars, which can be stored easily and in a space-saving manner, are either connected to the profiles at the factory or on site. The load-bearing capacity of the profiles, which can have minimal dimensions for the respective application, is specifically increased by means of the flat iron, while at the same time the load-bearing capacity is increased proportionally in the event of a fire.

• - die Figur 1 einen Querschnitt durch ein erfindungsgemässes Verbundprofil.
• - die Figur 2 eine Vorderansicht von einer weiteren Ausführungsform der Erfindung ohne Bewehrung und ohne Beton.
• - die Figur 3 einen Schnitt durch ein Flacheisen mit Bewehrung.
• - die Figuren 4 und 5 einen Quer-, resp. einen Längs-Schnitt durch zwei weitere Ausführungsformen des erfindungsgemässen Profils.

Some embodiments of the invention are explained in more detail below with reference to drawings. Show it:

• - Figure 1 shows a cross section through an inventive Composite profile.
• - Figure 2 is a front view of another embodiment of the invention without reinforcement and without concrete.
• - Figure 3 shows a section through a flat iron with reinforcement.
• - Figures 4 and 5 a transverse, respectively. a longitudinal section through two further embodiments of the profile according to the invention.

In Fig. 1 you can see an H-profile 1 whose chambers are filled with concrete 6. Flat bars 2 are welded onto both sides of the web. The welded joint 5 can be made continuously or by spot welding. Structural steel mats 3 provided with longitudinal reinforcement bars 4 are welded to the side of the flat bars 2. These prevent the concrete from flaking off due to heat.

The flat bars can have a thickness between 10 and 80 mm. In order to allow problem-free welding, the width of the flat iron is approximately 10 cm less than the web height. If the available flat bars are shorter than the profiles, several pieces are butted together. The flat bars should advantageously cover about 70% of the area of a web side.

Instead of attaching a flat bar in the middle of the web, in an advantageous variant two flat bars arranged in parallel can be welded to the web of the profile. The two flat bars can be arranged continuously, symmetrically or eccentrically. In the case of eccentric load distribution, as shown in FIG. 2, the flat iron 22 can extend over the entire height of the profile 1, while the flat iron 22a only extends to the level of a change in load, which can be caused, for example, by ceilings.

3 shows a further possibility for fastening the structural steel mats 33 provided with longitudinal reinforcement bars 34 to the flat bars 32. The headed pin dowels 38 are connected to the flat bars by means of electrical spot welding and the mats are hung into the dowels. The concrete then poured into the profile chamber causes the mats to be attached to the flat iron using the dowels.

The composite profile shown in FIG. 4 comprises, on both sides of the web, a plurality of flat iron 42 arranged one above the other, which are fastened to the web of the profile 1 by means of screw pins 48 and screw nuts 49. The number of flat iron 42 used can be selected depending on the required load and fire resistance. The structural steel mats or reinforcement baskets 43 provided with longitudinal reinforcement bars 44 are connected to the profile, similarly as set out above for the dowel fastening, by means of screw nuts or related elements 49a screwed onto the screw pin ends. Using simple measures, this embodiment leads to a composite profile that has different, for example height-dependent, properties with identical external dimensions. This profile is also ideally suited for construction on site. In order to achieve a quick assembly process, it is advantageous to provide both the profile 1 and the flat iron 42 with the required perforations in the factory. After assembly of the profile 1 and the flat iron 42, the profile is placed on the floor in such a way that both flanges lie on it. The structural steel mat 43 is then inserted and the elements 49a are turned onto the screw pin ends; the concrete is poured into the open chamber, formwork preventing it from running out at both open ends. In order to avoid the formation of concrete-free spaces, the concrete is advantageously vibrated. After the concrete has solidified, the composite profile is turned over and the same process steps are repeated. If you want to reduce the amount of reinforcing steel or avoid it altogether, it is recommended to use colloidal concrete or fiber-reinforced concrete instead of normal concrete.

Fig. 5 shows a longitudinal section through a profile on the web flat iron 52 are fastened by means of screws 58 and nuts 59. Raw screws as well as fitting screws or high-strength screws can be used as screws. In order to increase the forces acting on the friction surfaces, these were subjected to a surface treatment. The preparation of the friction surface can be carried out using shot blasted steel, sand or flame. In addition, the friction coefficients of the contact surfaces can also be increased by non-slip coatings or corrugation.

Claims (10)

1. Composite profile, in particular for supports, formed from concrete and a profile whose open chambers are largely filled with concrete, while the outer surfaces of the flanges of the profile have no concrete cover, characterized in that in the concrete at least one flat iron connected to the web of the profile is arranged. 2. Composite profile according to claim 1, characterized in that at least one flat iron is arranged centrally and continuously on both sides of the web. 3. Composite profile according to claim 1, characterized in that on at least one side of the web at least two flat irons are arranged alongside one another along the length. 4. Composite profile according to one of claims 1-3, characterized in that the different flat bars have the same dimensions. 5. Composite profile according to one of claims 1-4, characterized in that the flat bars are connected to the profile continuously or by spot welding. 6. Composite profile according to one of claims 1-4, characterized in that the flat bars are connected to the profile by means of screws guided through the web and nuts screwed thereon. 7. Composite profile according to claim 6, characterized in that the friction surfaces of the web or the flat iron at least partially have a surface which increases the coefficient of friction. 8. Composite profile according to one of claims 1-7, characterized in that the concrete is reinforced with reinforcing steel. 9. A composite profile according to claim 8, characterized in that the reinforced chamber concrete is connected to the flat bars via dowels or by means of screwing. 10. Composite profile according to one of claims 1-7, characterized in that the concrete is not reinforced with reinforcing steel, but consists of fiber-reinforced concrete, and this concrete is connected to the flat bars by means of dowels or screw connections.

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