DE20012824U1 - Fixed / loose flange construction or only loose flange construction for absorbing horizontal and diagonal tensile forces - Google Patents

Description

The invention relates to a fixed/loose flange construction or only a loose flange construction, also known as a plate anchor, for transmitting forces from two concrete components that are separated from each other by a seal and connected to each other by means of a screw connection. With this invention, horizontal forces can also be transmitted without causing bending in the connecting screw.

Description

The invention relates to a construction in which all forces between two concrete components that are separated by a seal but connected by a connecting screw can be transmitted without a bending moment being created in the connecting threaded part that connects the two concrete parts. It is irrelevant whether the components are reinforced concrete or prestressed concrete. The connecting threaded part naturally penetrates the seal. Such components according to the invention are essentially used in bridge construction or in ramp structures, e.g. in parking garages, but also in building construction, especially in double-shell components that are in contact with the ground. Such constructions are generally known as plate anchors or as anchors with a loose/fixed flange or as anchors with a loose flange if only one concrete part is being replaced in the event of renovation.

Such constructions are known and illustrated in DIN 18195 and in the relevant standard drawings of the Federal Ministry of Transport, especially in standard drawing Chapter 14 and in many company brochures. Recently, constructions have been developed that have limited mobility.

With loose/fixed flange anchors, a fixed flange anchor is installed flush in the first concrete, with an internal thread preferably being introduced into the bolt of this fixed flange anchor. After the seal has been applied to the concrete, a loose flange anchor is screwed to the fixed flange anchor using a screw, threaded rod or similar in such a way that a pre-tension is applied to the loose flange anchor in order to clamp the seal and thereby prevent any water on the seal from penetrating the first concrete when the screw penetrates the seal. In the case of renovation, a dowel construction, preferably designed as a chemical dowel, is inserted into the first concrete with a protruding external thread. After the seal has been applied, the procedure is analogous to that described above. The second concrete part can then be concreted and manufactured.

In bridge construction, damage has been seen in the screw shaft of such structures, especially when these plate anchors were subjected to high levels of horizontal forces, which are mainly caused by vehicles hitting the curb or kerb. The reason for this damage is the fact that the connecting screw has a lever arm that is at least as thick as the seal, until it is clamped in place.

This moment is not taken into account in static terms in most applications and for which a screw shaft or threaded rod is unsuitable due to its very low section modulus. In most cases, the lever arm is made even larger by unsuitable plate-anchor designs, so that the threaded part is subjected to even more stress. In order to keep this bending moment lower or to minimize the lever arm, some fixed flange designs are already butt welded so that the internal thread can begin at the upper edge of the fixed flange. With the loose flange, there were also considerations of making the through hole conical towards the bottom in order to force contact between the threaded rod and the loose flange as close to the seal as possible. However, loose flange designs with dowel fastening pose particular difficulties because the loose flange is spaced away from the other component by the thickness of the seal. In such cases, a moment must be followed based on the relevant regulations, which is influenced by a lever arm with the thickness of the seal plus the diameter of the anchor. In such cases, only the smallest horizontal forces can be absorbed within the permissible stresses. These regulations are also not taken into account in many applications due to a lack of structural offers on the market.

Longitudinally movable plate anchors are also known from company brochures and from patent number DE 19537399. However, these plate anchors are far less suitable for absorbing horizontal forces than the plate anchors described above, since with these plate anchors the bending moment becomes even greater in the event of diagonal pull due to the increased construction height caused by the design, and the bending moment from horizontal force must be superimposed on the bending moment from friction.

The present invention represents a loose/fixed flange construction or only a loose flange construction, which can absorb horizontal forces corresponding to the permissible shear forces and at the same time oblique tensile forces, whereby a bending moment in the connecting threaded part cannot arise at all due to construction parts according to the invention.

Taking into account the state of the art, the present invention fulfils the task of absorbing tensile forces and simultaneously horizontal forces, i.e. oblique tensile forces, without causing bending in the connecting screw.

The construction that is built into the first concrete is well known, but it must be designed in such a way that the thread begins immediately from the top edge of the fixed flange. No special measures are required for anchoring with dowels. The opening for the loose flange should preferably be circular. In special cases, however, openings with other shapes can also be useful, which can be square, rectangular or designed as an elongated hole. A threaded rod screwed into the fixed flange construction or, in the case of the dowel construction, the thread above the

A disk that acts as a shear disk and takes up the contour of the opening in the loose flange completely or partially only in the direction of the force is screwed directly onto the fixed flange or onto the first concrete using a nut using a thread protruding from the upper edge of the first concrete. This means that the seal must be completely removed in the area of this shear disk so that the fixed flange becomes visible in a fixed/loose flange construction or the first concrete in a dowel construction. This shear disk itself can also be provided with an internal thread so that it itself acts as a nut. The loose flange is now placed on the seal in such a way that the loose flange completely or partially encloses the screwed-on disk in the direction of the force. The construction must now be designed in such a way that the loose flange is pressed onto the seal using another nut. This can be achieved by using a suitable element, which does not absorb any forces from the concrete itself, to press the loose flange onto the seal using another nut, or by using suitable construction elements such as bracket constructions, which can absorb forces from the concrete themselves, to press the loose flange onto the seal.

The effect of absorbing horizontal forces through this construction is achieved by screwing the shear disk directly onto the lower part, i.e. without an intermediate seal. This means that the connecting screw is not subjected to bending, but only to shearing. The outer area of the disk rests against the opening of the loose flange and can transfer the horizontal forces to the loose flange via pressure. The tensile forces can be absorbed either by a construction attached to the threaded part or by anchor elements attached to the loose flange or by a bracket construction with which both the contact pressure can be applied to the loose flange and the tensile forces can be absorbed at the same time. With dowel anchoring, it is not necessary to take a moment into account if a steel part is screwed directly onto the concrete. This requirement is met by using the shear disk.

Of course, there are also different designs that can achieve the same transfer of horizontal forces. For example, it would be possible to design the shear disk together with the fixed flange as a structural unit in such a way that the shear disk protrudes over the fixed flange and is enclosed by an opening in the loose flange with the corresponding dimensions. The problem with this design variant, however, will be the protruding shear disk, which makes it considerably more difficult to remove the concrete from the surface. It would also be possible to design the disk as a structural unit with the loose flange, so that the shear disk is pressed directly onto the fixed flange. The disadvantage of this design, however, is that a tolerance-free thickness of the seal would be a prerequisite for the design in order to be able to maintain the clamping force on the seal. It is also possible to design the connecting screw with a very large diameter, but only to use it with the permissible bend, which would be very

would constitute uneconomical training.

Embodiments of the invention are illustrated in the accompanying drawings.

Fig. 1 a non-displaceable fixed/loose flange construction, whereby the shear disk is pressed onto the fixed flange by means of a threaded nut and the loose flange is clamped onto the seal by a bracket construction, which itself absorbs forces from the concrete

Fig. 2 a movable fixed/loose flange construction, whereby the shear disk itself is designed as a threaded part and is screwed onto the fixed flange and the loose flange is clamped onto the seal by a bracket construction that does not absorb any forces from the concrete itself

Fig. 3 shows a non-displaceable fixed/loose flange construction, whereby the shear disk is pressed onto the fixed flange by means of a threaded nut and the loose flange is clamped onto the seal by means of a bracket construction which itself does not absorb any tensile forces.

Fig. 4 a fixed loose flange construction with dowel, whereby the shear disk is screwed onto the first concrete by means of a threaded nut and the loose flange is clamped onto the seal by a bracket construction, which itself absorbs forces from the concrete

Fig. 5 shows a fixed loose flange construction with dowel, whereby the shear disk itself is designed as a threaded part and is screwed onto the fixed flange and the loose flange is clamped onto the seal by a bracket construction which does not absorb any tensile forces itself.

Explanation of the representation

Fig. 1 to 3 show a fixed flange construction consisting of the back anchor 1, to which the threaded sleeve 2 is welded, as is the fixed flange 3, so that the thread starts from the upper edge of the fixed flange. A seal 4 is placed on the bridge construction and the fixed flange 3. The threaded rod or screw 5 is then screwed into the threaded sleeve 2 of the fixed flange construction and the shear disk 6 is placed on the seal. In the area of this shear disk 6, the seal 4 is completely removed so that the fixed flange 3 becomes visible. The shear disk is now screwed directly onto the fixed flange 3, either as in Fig. 1 and Fig. using a threaded nut or, as shown in Fig. 2 , by manufacturing the shear disk 6 itself with a continuous internal thread and screwing it directly onto the fixed flange 3. The loose flange 7 is then placed with the bracket 8 on the seal 4 in such a way that the enlarged hole completely encloses the shear disk 6. The threaded nut 9 is used to achieve the contact pressure of the loose flange on the seal 4 and also to create the possibility of absorbing tensile forces. In Fig. 2 and Fig. 3, the

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Contact pressure of the loose flange on the seal is achieved. This element, like the other elements subordinate to the invention, is not limited to the shape and design shown in the illustration.

Fig. 2 shows a plate anchor that can be moved on one side. The hole in the loose flange must be designed as an elongated hole. It is advisable to also arrange friction-reducing plastic disks 14 between the loose flange and the element 10, which has the task of applying the contact pressure and transferring the tensile forces to the bracket 8, and the sliding disk 13 and the loose flange 7. A pipe section with a cover 12 is welded to the loose flange around the movable element 10 and an easily deformable element 15 is placed around the sliding disk in order to create the necessary clearance for the movement.
As can be seen from Fig. 3 , which is shown in a similar way to the examples in Fig. 1 and Fig. 2 , the type and appearance of the tensile force anchors are not limited to the illustration. If diagonal tension is to be absorbed, the anchor can take on any shape that is suitable for absorbing the diagonal tensile force. Fig. 4 shows a dowel construction 1. The shear disk 6 is screwed directly onto the concrete. Of course, the dowel anchor can also be designed to be movable, similar to Fig. 2. Movable anchors of this type are basically described in detail in the utility model no. 298 11 975.7.

Fig. 5 shows a loose flange construction with dowel 1, which is designed analogously to the other constructions with the difference that the elements 8 for force transmission are fastened to the loose flange 7 and the loose flange 7 is clamped onto the seal 4 via a bracket construction 10 and the nut 9.

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Claims (5)

1. Fixed/loose flange constructions or loose flange constructions as anchoring of two concrete components which are separated from each other by a seal and connected to each other by means of a screw connection to absorb horizontal or diagonal tensile forces, characterized in that the thickness of the seal is bridged by a transverse force disk so that a moment does not arise in the connecting screw between the two parts of the loose/fixed flange construction or loose flange construction. 2. Fixed/loose flange constructions or loose flange constructions as anchoring of two concrete components according to claim 1, characterized in that the shear disk is a separate structural element and is pressed onto the fixed flange by a type of screw connection and is partially or completely enclosed by the loose flange and the loose flange is additionally clamped onto the seal by a screw connection. 3. Fixed/loose flange constructions or loose flange constructions as anchoring of two concrete components according to claim 1, characterized in that the shear disk is part of the fixed flange and is partially or completely enclosed by the loose flange. 4. Fixed/loose flange constructions or loose flange constructions as anchoring of two concrete components according to claim 1, characterized in that the shear disk is part of the loose flange and is pressed onto the fixed flange with a threaded part while simultaneously clamping the seal. 5. Fixed/loose flange constructions or loose flange constructions as anchoring of two concrete components according to claims 1 to 4, characterized in that the constructions are designed to be longitudinally displaceable by means of an elongated hole in the loose flange and by the use of friction-reducing plastics and corresponding sliding elements.