DE29701591U1 - Reinforcement anchor - Google Patents

Abstract

The anchor comprises a U- or V-shaped base part (16v) with arms (24) adjoining the free arm ends of the base part. The arms run at an angle of more than 0 but less than 90 degs. relative to an axial extension of the base part arms and at an angle of more than 0 and less than 90 degs. relative to a plane spanned by the base part arms. The base part and the arms (24) can be integral. The anchor has a stretched S-shape. The anchor can be covered with a material which melts or burns off through heat action.

Description

The invention relates to a reinforcement anchor which is attached to a wall and serves to reinforce a fireproof lining (coating) applied to the wall.

The newly developed reinforcement anchor is particularly designed for attachment to so-called fin tube walls.

Fin tube walls are constructed analogously to Figure 1 (prior art). They consist of tubular elements 10 (hereinafter referred to as tubes) and surface sections 12 connecting the tubes 10. While one side of the fin tube wall is covered by a fireproof lining 14, insulation made of mineral wool, for example, can be applied to the other side.

Such finned tube walls are used in power plants, waste incineration plants or the like.

Turmstrasse 22 · D-40878 Ratingen ■ Telephone (0)2102/83088+842901 ■ Fax (0)2102/83069

The heat conducted from the combustion chamber through the refractory lining to the outside is conducted away via the pipes 10 through which a liquid flows and is thus recovered.

To secure the fireproof lining 14 to the finned tube wall, it is known (Figure 1) to weld short, cylindrical pins (16) onto the tubes as reinforcement, in different orientations. The disadvantage of this is that welding is carried out on the pressure-bearing tubes 10. The penetration during welding and repair work weakens the tube wall, which is undesirable and represents a safety risk.

In the state of the art, it has therefore already been proposed (Figure 2) to weld reinforcement anchors onto the surface sections 12 connecting the pipes 10. So-called wave anchors (Figure 2) and slotted pins (Figure 3) were used for this purpose.

The corrugated anchors run exclusively in the axial direction of the pipes 10 (Figure 2, right illustration) and can only be attached by manual welding. This method is both complex and does not provide an optimal reinforcement effect for the refractory lining 14.

The slotted pins are welded onto the surface sections 12 by hand welding, as marked 16a in Figure 3, and then split with a wedge along a central slot in the axial direction, as indicated by the reference number 16b. The disadvantage here is that the free end areas of the reinforcement anchors 16, which are important for the reinforcement function, have a very small cross-sectional area and therefore cannot absorb high loads. The cross-sectional area of the angled free end areas of the slotted pins is only about 30% of the

Cross-sectional area of the slotted pins at the welding point, since the axial slot (before bending) already removes material.

The object of the invention is to provide a reinforcement anchor of the type mentioned, in particular for use on fin tube walls, which avoids the aforementioned disadvantages, in particular is easy to install and can absorb large forces.

The invention is based on the knowledge that a corresponding reinforcement anchor must be designed in such a way that it can be fastened to the aforementioned surface sections between the pipes using a stud welding technique, has a largely constant material thickness over its entire longitudinal extension and is simultaneously shaped in such a way that it covers the area around the pipes that is particularly critical for the reinforcement function.

Such a reinforcement anchor, especially for fireproof linings on metal walls, has the following features in its most general form:

- A U- or V-shaped base part, as well as

- Arms that connect to the free leg ends of the base part, whereby the arms

- at an angle greater than 0 but less than 90° to an axial extension of the legs and

- run at an angle greater than 0 but less than 90° to a plane spanned by the legs of the base part.

The reinforcement anchor, which is preferably one-piece (single-piece), thus essentially comprises two sections, which

are designed differently and fulfil different functions.

The U- or V-shaped base part is used for fastening to the finned tube wall, specifically in the area of the surface sections mentioned above between adjacent tubes. This is done by stud welding, preferably using an electric arc. In this process, an electric arc with a high current intensity is ignited on the short side between the base part and the metal wall. The electric arc melts both parts, the parts are joined together and the current is switched off. The process can be carried out using either drawn arc ignition (DVS data sheet 0902) or tip ignition (DVS data sheet 0903).

In the case of a V-shaped base part, a more or less point-shaped weld connection to the wall is made. In the case of a U-shaped base part, a more or less linear or rectangular weld connection to the wall is made.

In order to be able to arrange a welding aid required for stud welding (an adapter in which the reinforcement anchor is aligned and held before the welding process) more easily in the area between adjacent pipes, the alignment of the anchor will generally be such that the plane spanned by the legs of the base part runs parallel to the longitudinal extension of the pipes and perpendicular to the wall, as shown in the following figure description.

Accordingly, the arms extend (both vertically and parallel to the wall) at a certain angle, which should be greater than 0 but less than 90°.

In other words, the arms do not run perpendicular to the axial direction of the tubes, but at a certain angle

starting from the connection area to the base part, slightly rising (i.e. corresponding to the shape of the adjacent pipes).

In this way - as shown in the following figure description - the pipes can be covered and thus the reinforcement anchor can be positioned in an optimized manner.

In preliminary tests, a reinforcement anchor has proven to be particularly advantageous whose base part has a V-shape (Figure 5) and which is S-shaped when viewed from above, preferably with an "elongated S-shape".

In order to avoid thermal stresses between the metallic reinforcement anchor and the ceramic refractory material as far as possible, the reinforcement anchor can have its surface at least partially covered with a material that melts or burns out under the influence of temperature.

This cover can, for example, be in the form of plastic caps that are placed on the free ends of the arms. However, the cover can also consist of a plastic coating that completely or partially covers the arms, which melts under the influence of temperature (under application conditions) and thus - like the caps mentioned - creates a free space between the reinforcement anchor and the refractory lining that compensates for thermal length changes.

Further features of the inventions emerge from the features of the subclaims and the other application documents.

The invention is described in more detail below using an embodiment.

Figures 4a, 4b and 4c show a reinforcement anchor according to the invention in different views, each highly schematic.

Figure 4a shows the basic structure of a fin tube wall, already known from Figures 1 to 3.

Reinforcing anchors 16 are welded onto the surface sections 12 by means of stud welding with an electric arc. Figure 4c shows the welding aid 18 used for this purpose with a receiving opening 20 for assembling the anchor and a chamber 22 formed on the underside into which the pointed end 16s of the V-shaped base part 16v of the anchor protrudes.

During arc welding, the armature 16 can be held securely between adjacent pipes 10 in this way. During the welding process, a type of protective gas atmosphere forms in the chamber 22, which supports the welding process.

A plurality of anchors 16 are welded onto the fin tube wall, resulting in an arrangement as shown in Figure 4b.

It can be seen that the arms 24 of the reinforcement anchor 16 are connected to the V-shaped base part 16v in a material-locking manner. The arms 24 each extend at an angle α of approximately 45° to the plane spanned by the V-shaped base part 16v El. The arms 24 are also angled relative to the axial extension of the legs of the base part 16v, here each at an angle β of approximately 55°.

As can be seen from the combination of Figures 4a to 4c, it follows that the reinforcing anchor 16 according to the invention is aligned with its base part 16v parallel to the axial direction of the pipes and its arms 24 cover adjacent pipes 10 at a distance.

The resulting reinforcement function for the refractory lining 14 has proven to be particularly favorable.

Figures 5 and 6 show the shape of the anchor in an exemplary design with a V-shaped base part 16v (Figure 5) and a U-shaped base part (Figure 6) as well as double-angled arms 24 with plastic caps 26 attached to the ends.

Claims (5)

Dr. Thomas U. Becker Rprkpr Ar* MU ÖJ Dr. Karl-Ernst Muller Diploma engineer DOC^i ^ IVJIJIIÖJ .. ,., _{; Diploma} engineer European Patent Attorney »gateijtan^te J J * *..&iacgr; .' European Patent Attorney Applicant: Dipl.-Ing. Peter Nebgen Josef-Zilliken-Straße 10 29, January 1997 56653 Wassenach VHI 24054 Reinforcement anchor B ■■ — nclaims 1. Reinforcing anchor, in particular for fireproof linings (14) on metal walls, characterized by a) a U- or V-shaped base part (16v) and b) arms (24) which connect to the free leg ends of the base part (&Igr;&bgr;&ngr;), and bl) at an angle greater than 0 but less than 90° to an axial extension of the legs and b2) at an angle greater than 0 but less than 90° to a plane El spanned by the legs of the base part (16v) get lost. Turmstrasse 22 · D-40878 Ratingen · Telephone (0)2102/83088+842901 ■ Fax (0)2102/83069 2 - 2. Reinforcement anchor according to claim 1, characterized in that the base part (16v) and the arms (24) are one-piece. 3. Reinforcement anchor according to claim 1, characterized by an S-shape in plan view. 4. Reinforcement anchor according to claim 3, characterized by an elongated S-shape in plan view. 5. Reinforcement anchor according to claim 1, characterized by at least a partial covering of the surface made of a material that melts under the influence of temperature or
burning material.