Heat radiation tube

Description

[0001] The present invention is for a heat radiation tube for furnaces and the like heating purposes. The source of heat can be electrical resistance elements or a burner using for example gas. Furnaces primarily means furnaces for heat treatment in industrial processes.

[0002] Heat radiation tubes are mainly used in furnaces where the furnace atmosphere does not allow direct heat. This can be due to that the atmosphere is harmful to the elements which are being used for electrical heating or a wish to control the atmosphere in the furnace whereby combustion gases are not allowed therein. Other reasons for the use of radiation tubes instead of direct heating where such should be possible might be for example that one wants to repair or exchange the heat source while the furnace is being used. It will then be easier to do this in a separate space, e.g. inside the radiation tube, than in the furnace chamber itself.

[0003] A heat radiation tube may comprise a cylindrical tube. A bottom is mounted in one end of the tube. In the other end of the tube there is as a rule a flange for mounting in the furnace wall. The tube can also have other arrangements, protrusions, etc. for mounting in the furnace as well as distance pieces and the like. Mainly when heating is obtained by combustion there may in the tube be inserts forming flow channels for the combustion gases. There are also U-shaped radiation tubes.

[0004] Radiation tubes have hitherto mainly been used by furnace temperatures up to about 1100°C. The tubes are often made from an alloy mainly comprising nickel, chromium and iron. The alloy composition is for example 40-60 weight % nickel, 15-20 % chrom and 25-45 % iron. These radiation tubes, however, have certain drawbacks which are of great importance in most application. On the surfaces of the tubes the outside as well as the inside oxide layers are formed which are spalled off when they have reached a certain thickness, which varies due to conditions in each application. Hereby the oxide layers do not give protection against continuing attacks on the tubes. Downfalling oxide flakes may cause problems if they get into contact with the products which are present inside the furnaces. However, the greatest problems are caused by the oxide flakes inside the tubes. If these are holding electrical elements for the heating the flakes may cause short-circuiting between separate elements and between separate parts of one element which brings with it an immediate interruption of the function of the element or a considerably decreased life of the element. When an element is exchanged, which means that element and element support is pulled out from the radiation tube and after repair or exchange again is pushed into it,the supports may function as scrapes and bring about heaps of oxides in most cases in the far end of the tube which may cause difficulties by the repair work and function deficiencies.

[0005] A radiation tube made of a FeCrNi alloy and comprising a heating element is disclosed in US-A-3,137,486. However, as explained above, the oxide layer is not stable at very high temperatures, which is a serious drawback. Furthermore, hitherto used radiation tubes do not have satisfactory mechanical properties by high temperatures of use. Due to their own weight and the internal load the tubes tend to sag. In order to compensate for this the tubes have to be turned 180° at regular intervals. This can in most cases be made in connection with normal maintenance or repair but it is still an important drawback and a factor which limits the possibilities of use.

[0006] The object of the present invention is to avoid the above-mentioned drawbacks of hitherto known radiation tubes and to make possible a higher temperature of use than has hitherto been possible. This mainly refers to a higher constant temperature by continuous use. The invention also makes it possible to have longer intervals between stops for maintenance works. The much reduced or totally eliminated sagging of the tubes means much for reliable function of the radiation tubes as well as easier maintenance.

[0007] Radiation tubes according to the invention are intended for use in furnaces and the like heating purposes and are characterized in claim 1. A method of producing the tube is defined in claim 3. Optional features of the invention are set out in the dependent claims. The cylindrical seamless sheath tube is made from an alloy of FeCrAl whereby a FeNiCr alloy is excluded . These radiation tubes have important advantages compared to conventional tubes made by casting or welding of plates from nickel chromium or iron-nickel-chromium-alloys. Radiation tubes according to the invention can be used at temperatures up to 1250-1300°C.

[0008] At high temperatures FeCrAl-alloys at oxidizing conditions form a stable and adhering layer of aluminium oxide on the surface of the material. This oxide is also more heat resistant and resistant against chemical attacks than the layers which are formed on nickel-chromium-alloys. This is particularly obvious in sulphur containing environments, where rapid and severe attacks are obtained on nickel-chromium materials. If the oxide layer is undamaged the FeCrAl-alloys are better also in carburizing atmosphere. In many applications forming the oxide layer by preoxidization according to the invention is therefore important also if the intended temperature of use is below 1100°C. Suitable pre-oxidation is for example heat treatment in air at 1100°C for at least 8 hours. The FeCrAl-alloy may also contain minor amounts of other alloying components such as yttrium, titanium and zirconium in amounts up to 0.2 weight % of each. These additives influence the oxide layers as well as the structure and properties of the material.

[0009] The cylindrical tube which is a main part of the radiation tube is seam-less and preferably made by extrusion. The slab which is used for the extrusion is made in a well-known way be casting or by powder metallurgy. The shearing speed and other conditions by extrusion are choosen to give the tubes a striped surface which means that all of the outer surface of the tubes is rough with axially extending irregular grooves and ridges, the size of which is chosen to optimize the properties of the oxide layer, mainly its strength and elasticity, in order to avoid oxide spalling by high temperatures and changing temperature.

[0010] Below the invention will be further described with reference to the accompanying figures.

Fig. 1 shows electrically heated radiation tubes inside a furnace. One of the radiation tubes is shown with part of the tube cut away in order to show the element.

Fig. 2 shows a cross section through a radiation tube which is heated by combustion of gas.

Fig. 3 shows the surface of the cylindrical tube of a radiation tube.

Fig. 4 shows a cross section of the cylindrical tube.

[0011] Fig. 1 shows several radiation tubes (1, 2A, 2B) which have been mounted into a furnace, whereof a brick wall (3) is shown. The radiation tubes have a sheath which is a cylindrical tube (9) made from FeCrAl material. FeCrAl material means iron-chromium-aluminium-alloys as described above. At the outer end of the tube is a wall (not shown) from the same material. Into the wall (3) of the furnace is opened a hole which corresponds to the tube and wherein the end of the tube is supported. For the not shown end of the tube there is a corresponding support, for example a shelf or an opening in the furnace wall. The distance between the walls of the furnace can be up to 2 meters and the radiation tube is hanging unsupported therein between. Inside the tube there is an electrical resistance element (4) which in the example shown is made from MoSi₂ of the kind which is marketed under the trademark KANTHAL SUPER. The element is resting on a ceramic support (5). The terminal parts (7) of the element pass through two plugs (6, 8), which separate the hot atmosphere of the radiation tube from the surroundings and support the terminal parts.

[0012] The radiation tube shown in Fig. 2 is intended to be heated by an indicated gas burner (14). The combustion gases from the burner flow firstly through the insert (12), make a turn at the wall (10) and flow back along the radiation tube (9). The latter has a flange (11) for mounting to the furnace wall in a conventional way. Supports (13) are welded to the insert.

[0013] The radiation tubes shown in figures 1 and 2 have dimensions chosen with respect to the furnace wherein they are to be used. For example, the length of the tube may be 1800 mm, its external diameter 200 mm and wall thickness 8 mm.

[0014] Figures 3 and 4 show the appearance of a radiation tube according to the invention. Figure 3 is a photograph of the surface of the tube and figure 4 shows a cross section of the same surface of the tube at about 50 times magnification. The striped appearance of the surface is shown in the pictures. These crystal stripes are obtained by the use of a sufficient high shearing speed at the extrusion process and can be essential for the properties of the oxide layer.

Claims

1. Heat radiation tube for furnaces and the like, comprising a cylindrical tube made from an alloy with an outer oxide layer and having heating elements, characterized in that

- the cylindrical tube is a seamless sheath tube (9) made from a FeCrAl alloy, wherein a tube made from a FeNiCr alloy is excluded; and

- the oxide layer on the outer surface of the sheath tube (9) comprises mainly aluminium oxide and was made stable and adhering by preoxidation.

2. Heat radiation tube according to claim 1,
characterized in that the outer surface of the sheath tube (9) is rough having irregular grooves and ridges extending along the tube.

3. Method of producing a heat radiation tube for furnaces or the like, comprising a cylindrical tube made from an alloy with an outer oxide layer and having a heating element, characterized in that

- the heat radiation tube (1) is formed by disposing the heating element (4) inside a sheath tube (9);

- the sheath tube (9) being made by extrusion of a FeCrAl alloy, wherein a tube made from a FeNiCr alloy is excluded; and

- the outer oxide layer, on the outer surface of the sheath tube (9) comprising mainly aluminium oxide and being made stable and adhering by preoxidation.

4. Method according to claim 3, characterized in that the extrusion is made at such a shearing speed that the outer surface of the sheath tube (9) is rough having irregular grooves and ridges extending along the tube.

Ansprüche

1. Wärmestrahlungsrohr für Öfen und dergleichen, welches ein aus einer Legierung mit einer äußeren Oxidschicht gefertigtes zylindrisches Rohr umfasst und Heizelemente aufweist, dadurch gekennzeichnet, daß

- das zylindrische Rohr ein nahtloses Hüllrohr (9) ist, hergestellt aus einer FeCrAl-Legierung, wobei ein aus einer FeNiCr-Legierung hergestelltes Rohr ausgeschlossen ist; und daß die Oxidschicht auf der äußeren Oberfläche des Hüllrohrs (9) im wesentlichen Aluminiumoxid umfaßt und durch Voroxidation stabil und anhaftend gemacht wurde.

2. Wärmestrahlungsrohr nach Anspruch 1, dadurch gekennzeichnet, daß die äußere Oberfläche des Hüllrohrs (9) rau ist und unregelmäßige sich entlang dem Rohr erstreckende Nuten und Rippen aufweist.

3. Verfahren zum Herstellen eines Wärmestrahlungsrohrs für Öfen oder dergleichen, umfassend ein zylindrisches Rohr, welches aus einer Legierung mit einer äußeren Oxidschicht hergestellt ist und welches ein Heizelement aufweist, dadurch gekennzeichnet, daß

- das Wärmestrahlungsrohr (1) durch Anordnen des Heizelements (4) im Innern des Hüllrohrs (9) hergestellt wird;

- daß das Hüllrohr (9) durch Extrusion einer FeCrAl-Legierung gefertigt wird, wobei ein aus einer FeNiCr-Legierung gefertigtes Rohr ausgeschlossen ist; und

- daß die äußere Oxidschicht auf der äußeren Oberfläche des Hüllrohrs (9) im wesentlichen Aluminiumoxid umfasst und mittels Voroxidation stabil und anhaftend gemacht wird.

4. Verfahren nach Anspruch 3, dadurch gekennzeichnet, daß die Extrusion mit einer solchen Schergeschwindigkeit durchgeführt wird, daß die äußere Oberfläche des Hüllrohrs (9) rau ist und unregelmäßige Nuten und Rippen aufweist, welche sich entlang dem Rohr erstrecken.

Revendications

1. Tube de rayonnement de chaleur pour fours et analogues, comprenant un tube cylindrique fait d'un alliage avec une couche d'oxyde externe et comportant des éléments de chauffage, caractérisé en ce que :

- le tube cylindrique est un tube à manchon sans soudure (9) fait d'un alliage Fe-Cr-Al, un tube fait d'un alliage Fe-Ni-Cr étant exclu; et

- la couche d'oxyde sur la surface externe du tube à manchon (9) comprend principalement de l'oxyde d'aluminium et devient stable et adhésive par pré-oxydation.

2. Tube de rayonnement de chaleur selon la revendication 1, caractérisé en ce que la surface externe du tube à manchon (9) est rugueuse, comportant des rainures et des nervures irrégulières s'étendant le long du tube.

3. Procédé de fabrication d'un tube de rayonnement de chaleur pour fours ou analogues, comprenant un tube cylindrique fait d'un alliage avec une couche d'oxyde externe et comportant un élément de chauffage, caractérisé en ce que :

- le tube de rayonnement de chaleur (1) est formé en disposant l'élément de chauffage (4) dans un tube à manchon (9);

- le tube à manchon (9) étant fabriqué par extrusion d'un alliage Fe-Cr-Al, un tube fait d'un alliage Fe-Ni-Cr étant exclu; et

- la couche d'oxyde externe, sur la surface externe du tube à manchon (9), comprenant principalement de l'oxyde d'aluminium et devenant stable et adhésive par pré-oxydation.

4. Procédé selon la revendication 3, caractérisé en ce que l'extrusion est réalisée à une vitesse de cisaillement telle que la surface externe du tube à manchon (9) est rugueuse, comportant des rainures et des nervures irrégulières s'étendant le long du tube.

Drawing