DE4109706C2 - Concrete installation element - Google Patents

Description

The invention relates to a concrete installation element according to the Preamble of claim 1.

Under "concrete installation element" is entirely in the sense of the invention to generally understand a component for concrete construction, which is made of steel and at least in a partial area this sub-area has at least one surface with which the concrete installation element when used in concrete or Cement of a building is embedded or anchored. Such concrete installation elements can be the most varied Function and thus also the most diverse training exhibit. Such installation elements are for example Formwork in the form of lost formwork elements, such as Elements of quiver formwork, expanded rib metal, Verwah Reinforcement elements of so-called reinforcement connections etc. Furthermore are concrete built-in elements such as bars for walls strengthen or formwork anchors, d. H. for example rod-shaped Elements that are used to make two each other Opposing formwork walls of a concrete formwork in one keep predetermined distance etc.

There is a problem with concrete parts basically in the fact that often at the transition between the Concrete installation element and the adjacent concrete or cement especially not moisture-proof closure or can only be guaranteed with special measures.

A non-magnetic steel material is known (DE-OS 29 08 575), which is provided with a coating, the zinc, May contain aluminum and / or tin. This coating serves as corrosion protection.

In contrast, the invention is based on the object to show a concrete installation element, in which a particularly tight closure or transition between Concrete installation element and concrete or cement is ensured.

To solve this problem, a concrete installation element is ent speaking the characterizing part of claim 1 educated.

The invention lies u. a. based on the knowledge that through a particularly intimate and firm embedding of the concrete Installation element in concrete or cement problems regarding tightness can be avoided. This particularly intimate and firm integration is achieved in that the layer Aluminum or from the aluminum alloy with the free lime of the cement with the participation of oxygen to one Calcium aluminate reacts, which is firm and dense Integration of the concrete installation element ensured so that especially with static or dynamic loads there are no cracks etc. at the transition from the concrete to the installation element surrender.

By using the concrete installation according to the invention So a concrete structure is obtained in the element this installation element is firmly and tightly integrated, namely such that even with static or dynamic loads there are no cracks etc. at the transition from the concrete to the installation element surrender.

In the invention, the thickness of the aluminum layer or Layer made of aluminum alloy selected so that the The concrete sets sufficient calcium aluminate formation occurs and at the end of this reaction at most only a residual layer made of aluminum or aluminum alloy tion with a very small thickness remains.

Further developments of the invention are the subject of the sub Expectations.

The invention is illustrated below with the aid of the figures Exemplary embodiment in the form of a reinforcement connection explained. Show it:

Fig. 1 in cross section a reinforcing terminal or a serving for insertion in a formwork for a concrete supply apparatus;

Fig. 2 and 3, a part of the length of the embedded first created in a concrete component device in longitudinal section and a cross sectional view similar to Figure 1 but components together with two adjoining concrete.

Fig. 4 shows a section along the line II in FIG. 1.

In the figures, 1 is a reinforcement connection, that is to say a device for inserting into a formwork for a concrete component, which essentially consists of a box-shaped or profile-shaped storage element 2 and of several U-shaped brackets or reinforcement bars each produced from lengths of reinforcing steel by bending 3 exists.

The storage element essentially has a bottom 4 and two in one piece with this bottom by bending Herge legs 5 , which protrude from a common side of the bottom 4 and enclose with this an acute angle such that there is a dovetail-shaped profile for the storage element 2 . Each reinforcing bar 3 has two legs 6 , which are connected to each other via a yoke section 7 and are each composed of two leg sections 6 'and 6 ''which are angled at right angles to one another. The bow-shaped reinforcement bars 3 are guided with their legs 6 through corresponding openings in the bottom 4 such that the brackets 3 with their leg sections 6 'passing into the yoke section 7 ' project approximately perpendicularly beyond the outside of the floor 4 from the interior 8 of the storage element 2 , while the leg sections 6 '' running approximately parallel to the level of the bottom 4 in the interior 8 of the storage element 2 are seen, closed on the opposite side of the floor 4 by a cover and at the two ends of the storage element 2 by appropriate end pieces is.

The reinforcement connection 1 is used in a manner known per se, ie the storage element 2 preassembled with the reinforcement bars 3 is in a formwork for the creation of a first concrete component, for example the concrete wall 9 , where another concrete component, for example the concrete wall, is connected to this concrete wall 10 to be connected later, arranged in such a way that the open side of the storage element 2 , which is closed by a cover, is located directly on the inner surface of the formwork for the concrete wall 9 . After the completion of the concrete wall 9 , the storage element 2 and the reinforcing bars 3 with their leg sections 6 'and their yoke section 7 are embedded in the concrete of this concrete wall and after the formwork has been removed from the concrete wall 9 , the angled leg sections 6 ''can be bent, as shown in FIG is indicated. 2 by the arrow A, so that then the bent leg portions 6 '' in the concrete of the concrete wall to be embedded in the manufacture of the concrete wall 10. The storage element 2 consisting essentially of sheet steel remains as lost formwork in the concrete between the concrete walls 9 and 10 .

Although the storage element 2 is completely covered by the concrete of the concrete walls 9 and 10 , it cannot be ruled out that there will be leaks at the transition area between the concrete and the storage element 2 , due to the moisture in particular not only to the storage element but also to the the connecting reinforcement between the concrete walls 9 and 10 reinforcing bars 3 arrives and thus there occurs corrosion. To avoid this and to achieve a transition between the storage element 2 and concrete without leaks, are the depository element 2 or its base 4 and legs 5 of a steel plate 11 is made, which both at the inner side of the flashing element 2 as well as on the the outer side of this surface element forming the storage element is provided with a layer 12 of aluminum or an aluminum alloy. In the embodiment shown, each layer 12 has a thickness d that is only relatively small in relation to the thickness D of the steel sheet 11 , that is to say d is 20 micrometers, for example, while the thickness D of the steel sheet is greater than 0.3 mm, that is to say on the order of 0.3 mm and 1.0 mm.

If an aluminum alloy is used for the layers 12 , this contains, for example, more than 50%, e.g. B. 55-75% aluminum, the rest being at least partially formed by zinc.

When the concrete of the concrete walls 9 and 10 sets, the material of the layers 12 reacts with the cement or with the free lime and oxygen to calcium aluminate, which results in a particularly intimate connection between the storage element 2 and the subsequent concrete. The thickness d of the layers 12 is chosen so that, on the one hand, the calcium aluminate formation required for the tightness, ie the integration of the storage element 2 , is ensured to the extent necessary, but on the other hand after completion of the calcium aluminate formation, ie after the concrete has set on the steel sheet 11 the necessary integration is still ensured and in particular there is no loss of strength at the transition area between the concrete and the storage element 2 and also no electrolytic elements which could cause corrosion of the reinforcing bars 3 forming the reinforcing bars 3 .

In one embodiment of the invention, each layer 12 is formed by an aluminum alloy, which has the following composition:
approx. 55% aluminum
approx. 43% zinc
about up to 2% silicon.

The proportion of silicon here is preferably about 2% or 1.6%.

The thickness d of each layer 12 in this embodiment is approximately in the range between 10 and 40 micrometers, preferably in the range between approximately 20 and 25 micrometers.

The invention was discussed above using the exemplary embodiment of the reinforcement connection 1 . It goes without saying that numerous further embodiments of the invention are conceivable, ie in principle the invention can be used with all concrete built-in elements made of steel or sheet steel.

Claims (12)

1. Concrete installation element, which is made of steel at least in a partial area and has at least one surface to be embedded in concrete or cement, which is provided with a layer ( 12 ) of aluminum or an aluminum alloy, characterized in that the layer of aluminum or aluminum alloy has a thickness (d) of less than 200 micrometers and which is selected such that after the embedding of the installation element ( 2 ) in the concrete or cement and after the concrete has set, almost the entire material of the layer ( 12 ) made of aluminum or has reacted from an aluminum alloy with the free lime of the concrete or cement and with oxygen to form a calcium aluminate, at most to a small remaining thickness, in order to achieve an intimate and firm connection between the concrete installation element and the concrete. 2. Concrete installation element according to claim 1, characterized indicates that the thickness of the layer of aluminum or Aluminum alloy in the order of 20 microns lies. 3. Concrete installation element according to claim 1, characterized in that the thickness of the layer ( 12 ) made of aluminum or of the aluminum alloy is in the range between about 10-40 microns. 4. Concrete installation element according to claim 1, characterized indicates that the thickness of the layer on aluminum or aluminum alloy is about 20-25 microns.   5. Concrete installation element according to one of claims 1-4, characterized in that the layer forming Aluminum alloy contains zinc, the proportion of Aluminum is greater than 50%, preferably between about 55-70% lies. 6. Concrete installation element according to claim 5, characterized indicates that the aluminum alloy forming the layer contains about 55% aluminum and about 43% zinc. 7. concrete installation element according to claim 6, characterized records that the aluminum alloy accounts for about Contains 2% silicon. 8. Concrete installation element according to claim 7, characterized records that the aluminum alloy is about 1.6% silicon contains. 9. Concrete installation element according to one of claims 1-8, characterized in that the element ( 2 ) is made at least in a partial area from a steel sheet ( 11 ), which on at least one surface side, but preferably on both surface sides, each with the layer ( 12 ) is made of aluminum or aluminum alloy. 10. Concrete installation element according to one of claims 1-9, characterized by its design as a custody element ( 2 ) of a reinforcement connection, as a joint sheet, as expanded metal, as formwork, preferably quiver formwork. 11. Concrete installation element according to one of claims 1 to 9, characterized in that the built-in element at least in a partial area from a rod-shaped element Steel is formed, which with the layer of aluminum or is made of an aluminum alloy.   12. Concrete installation element according to claim 11, characterized by his training as a staff for wall strengths or as Formwork anchors.