WO2004057227A1 - Holding device for fixing a ceramic pipe - Google Patents

Abstract

The invention relates to a holding device, which is provided for a ceramic pipe (3) and comprises a metallic adapter (1) and a seal (2). The holding device is characterized in that the seal (2) is made of a material that expands when the temperature is increased, and the fixing of the ceramic pipe (3) inside the metallic adapter is effected by the seal (2).

Description

Holding device for fixing a ceramic tube

The invention relates to a holding device for fixing a ceramic tube without a groove or flange.

A number of possibilities are known for fixing ceramic pipes to the associated systems: concreting in;

Gluing a threaded metal tube on the inside of the ceramic tube;

Clamping a metallic adapter to a flat groove made in the ceramic tube;

Clamping a metallic adapter via set screws to a round groove made in the ceramic; - Clamping a metallic adapter to a flange belonging to the ceramic tube.

For fastening and holding ceramic pipes open on one or both sides, such as thermocouple protection pipes, heating pipes, riser pipes, metering pipes, degassing rotors, blowing lances and similar, hereinafter referred to as ceramic pipes, on devices in which non-ferrous metals are processed, such as pressure and low-pressure casting furnaces. Pre-and shaft melting furnace, holding furnace and similar equipment in foundries, metal adapters are used, which either engage in one or more grooves made in the ceramic tube or are clamped to an outwardly pronounced flange and thus hold the tube in position.

So far, only the clamping processes have been used for thin-walled ceramic tubes made of silicon nitride. The design of the clamp and the external design of the adapter are very different (rigid screw connection, spring damping such as: described in DE4419245C2, flexible ball head, attachment to an external flange), but in all embodiments there is the principle of using either two half-shells reach into a flat groove and held together by a union nut or to reach into a round groove with side set screws or to fix multi-part metal flanges to a circumferential flange belonging to the ceramic tube. The major disadvantage of these brackets in the case of grooves is the weakening of the material by reducing the wall thickness by 1.5-5mm. In addition, the groove acts as a notch on which stress peaks form. If flanges are used, a lever acts from the metal flange on the ceramic flange, which also leads to voltage peaks. These grooves or flanges are the weak points of the pipes against mechanical stress.

In everyday use, ceramic tubes are often unintentionally hit with the end opposite the holder against any obstacles. The flat or round groove or the flange is therefore the weakest point of the pipe, to which forces are simultaneously applied using the largest possible lever. In the foundries' practice, a pipe break in the groove area is responsible for at least 60 percent of all ceramic pipe failures.

The object of the invention is to provide a holding device for a ceramic tube, which reduces the risk of breakage of the ceramic tube.

The present invention relates to a holding device for a ceramic tube, which comprises a metallic adapter and a seal, characterized in that the seal consists of a material which expands when the temperature rises and fixes the ceramic tube in the metallic adapter through the seal becomes.

The arrangement preferably consists of an internal ceramic tube and an external metallic adapter. The seal then encompasses the ceramic tube and the adapter encompasses the seal.

The adapter preferably forms a metal tube which envelops the upper region of the ceramic tube. Various export shapes of the adapter are shown in the figures. The surface of the adapter facing the seal is preferably structured. The strength of the seat of the ceramic tube can be increased further. The structuring is, for example, round or square grooves or a corrugation of the surface facing the seal. This improves the adhesion of the seal.

There is a gap between the ceramic and metal pipe, into which a seal is pressed, which expands as the temperature rises and contracts again as the temperature falls. The adapter is attached in the usual way to the associated system or part of this system. For example, the adapter is provided on the outside with one or more grooves, a flange or a thread which enables attachment to the system or measuring device.

A temperature-dependent material that is also used as a seal has been known for a long time and is found e.g. application in autocatalysts.

There it ensures that the ceramic catalyst is securely seated in the metallic casing, which expands rapidly at operating temperature. Without the seal, the strong vibrations during operation would quickly destroy the catalyst. The sealing materials used there are preferably also used in the seal according to the invention.

The seal is preferably an elastic seal, particularly preferably an elastic fiber seal. It preferably contains 15-70% by weight vermiculite, 15-70% by weight aluminum silicate and 15-70% by weight Montmonllomte. When heated from 20 ° C. to 700 ° C., the seal preferably has a thermal expansion of 10 to 100 percent, particularly preferably 20 to 50 percent. The gap between the ceramic and metal pipe is preferably designed in such a way that the seal to be inserted must be compressed to 50-70 percent of its original thickness.

The gap between the ceramic and metal tube is preferably 2 to 20 millimeters, particularly preferably 4 to 15 mm.

In the cold state, the friction between the ceramic tube and seal on the one hand and the seal and metal tube on the other hand is sufficient to hold the ceramic tube in position in the holder according to the invention. With increasing temperature, both metal and ceramic pipe expand. Due to the higher thermal expansion of the metal, the inner ceramic tube would loosen and fall out of the holder without a special seal according to the invention. This is prevented by the high thermal expansion of the intermediate seal. The friction between the individual components is retained and the ceramic tube remains in its position at any temperature. When cooling down, the process is reversed.

For the first time, the holding device according to the invention enables ceramic tubes to be fixed without a groove or flange in the area of the metallic adapter.

In order to further increase the fixation of the ceramic tube, the outer surface of the ceramic tube can be provided with a structure that additionally increases the friction.

Such structures are, for example, fine indentations or a corrugation on the surface of the ceramic tube facing the seal. These structures are so fine that they do not fulfill the function of the standard holding grooves of a ceramic tube (for example a thermocouple protection tube).

In the holding area in which the ceramic tube is encompassed by the seal and the seal by the metallic adapter, the ceramic tube therefore does not require a flange or a round or flat groove for fixation. This eliminates this reason for failure of the ceramic tube. The elastically deformable seal additionally absorbs impacts and thus further reduces the risk of breakage. The risk of breakage is reduced not only by the fact that a groove on the ceramic tube is no longer necessary, but also by the resulting surface pressure on the seal, which greatly reduces the voltage peaks even when there is a groove.

The holding device according to the invention is preferably suitable for fixing a thermocouple protection tube or a riser tube or a heating tube or a dosing tube or an injection lance or degassing rotors or silicon nitride tubes or Sialon tubes.

The elastic seal is preferably pressed into the structures at room temperature during assembly and thus additionally secured against slipping.

The holding device according to the invention is assembled, for example, as follows:

The seal is placed in the metal pipe and then the ceramic pipe is pressed into the seal.

^■ The seal is placed around the ceramic tube and the metal tube is pressed onto the seal.

^■ The seal is placed around the ceramic tube and pressed together using a special tool. Then the metal tube is pushed on and the tool is removed. The seal springs back elastically and presses itself into the metal tube.

^■ The seal is placed around the ceramic tube and around it two metallic half-shells are placed which, when they are joined together, compress the seal. To fix the half-shells, a metal tube is pushed on the outside. The holding device according to the invention is preferably suitable for all of the fastenings and holders of ceramic pipes already mentioned, particularly preferably for fixing ceramic pipes to plants in foundries.

The figures show different embodiments of the invention.

Fig. 1 shows a holding device according to the invention from adapter and seal with a thermocouple protection tube. 2 shows a holding device according to the invention comprising an adapter and a seal with a thermocouple protection tube, the ceramic tube and adapter having a structured surface. Fig. 3 shows a holding device according to the invention from adapter and seal with a metering tube. FIG. 4 shows a holding device according to the invention comprising an adapter and a seal with a metering tube, the ceramic tube and adapter having a structured surface. 5 shows a holding device according to the invention comprising an adapter and a seal with a blowing lance. 6 shows a holding device according to the invention comprising an adapter and a seal with a blowing lance, the ceramic tube and adapter having a structured surface. 7 shows a holding device according to the invention comprising an adapter and a seal with a degassing rotor. 8 shows a holding device according to the invention comprising an adapter and a seal with a degassing rotor, the ceramic tube and adapter having a structured surface. 9 shows a holding device according to the invention comprising an adapter and a seal with a riser pipe. 10 shows a holding device according to the invention comprising an adapter and a seal with a riser tube, the ceramic tube and adapter having a structured surface. 11 shows a holding device according to the invention comprising an adapter and a seal with a conical riser pipe. 12 shows a holding device according to the invention comprising an adapter and a seal with a conical riser tube, the ceramic tube and adapter having a structured surface In the drawings:

1 adapter (metal tube)

2 seal

3 ceramic tube 4 surface structure in the adapter

5 surface structure in the ceramic tube

6 Dosing opening

The following example serves to further explain the invention.

For example:

Ceramic tube made of silicon nitride (outer diameter 28mm; mass

2000g) adapter: metal tube (inner diameter 40mm)

Gap dimension: 6mm;

Seal: 10mm; Commercially available under the name

Interam ™ 100 from 3M

The seal was placed in the metal tube and then the ceramic tube was pressed into the seal.

The holding device was exposed to a temperature cycle of room temperature (20 ° C.) -> 800 ° C. 5 times. After the end of the test, the seat of the ceramic tube in the adapter was unchanged.

Claims

claims 1. Holding device for a ceramic tube which comprises a metallic adapter and a seal, characterized in that the seal consists of a material which expands when the temperature rises and the fixing of the ceramic tube in the metallic adapter is effected by the seal. 2. Holding device according to claim 1, characterized in that the adapter is a metal tube which envelops the upper region of the ceramic tube. 3. Holding device according to claim 1 or 2, characterized in that the seal is an elastic seal, preferably an elastic fiber seal. 4. Holding device according to claim 3, characterized in that it contains 15-70 percent vermiculite, 15-70 percent aluminum silicate and 15-70 montmorillonite. 5. Holding device according to one or more of claims 1 to 4, characterized in that the seal when heated from 20 ° C to 700 ° C has a thermal expansion of 10 to 100 percent, particularly preferably from 20 to 50 percent. 6. Holding device according to one or more of claims 1 to 5, characterized in that the gap between the ceramic and metal tube is designed so that the seal to be added must be compressed to 50-70 percent of its original thickness. 7. Holding device according to one or more of claims 1 to 6, characterized in that the ceramic tube has no groove or flange in the region of the metallic adapter. 8. Use of a holding device according to one or more of claims 1 to 7, for fixing a thermocouple protection tube or a riser tube or a heating tube or a dosing tube or a blowing lance or of degassing rotors or silicon nitride tubes or or silicon tubes. 9. Use of a holding device according to one or more of claims 1 to 7, for fixing ceramic tubes to plants in foundries.