SE0801515A0 - Industrial furnace lining - Google Patents

Description

10 15 20 25 30 Thus, the invention relates to a lining element for one comprising a first industrial furnace, layer of one first refractory material, and is characterized in that the surface of the lining element which is intended to face the oven heated volume. at least partially coated with. a second layer of a second refractory material, where the second material is porous.

The invention will now be described in detail, with reference to exemplary embodiments of the invention and those attached drawings, where: Figure 1 is a schematic cross-sectional side view of an info- according to a first preferred embodiment of the present invention. the invention.

Figure 2 is a schematic cross-sectional side view of an infod according to a second preferred embodiment of the present invention.

Figure 3 is a detail view from above of the lining shown in figure l.

Figure 1 illustrates a part of a liner according to a preferred an embodiment of the present invention, in the form of a liner element 1 for mounting inside the heated volume but in an industrial furnace. Suitable uses for one such lining element 1 is together with other elements as part of a roof, floor or wall cladding inside a oven.

The lining 1 comprises a first, lower layer 2 made of a refractory material, and is according to a preferred embodiment pïïparranoransokningsxextdoc, 3008-06-15 10 15 20 25 30 ring shape solid. The lower layer 2 acts as an insulating and supportive and also contributes to the strength of the element.

Suitable materials for the lower layer are such castable material that has high heat resistance, for example ceramic materials such as various aluminum, zirconium or silicon oxides. Over parts of the surface of the lining element 1 which is intended to be facing the heated volume of the oven during operation the lower layer 2 coated with an upper layer 3. The upper layer 3 is, like the lower layer 2, made of a fire- solid material, preferably a ceramic material such as Algh. The upper layer 3 can, but does not have to, be manufactured of the same material as the lower layer 2.

According to the present invention, the upper, towards the top of the oven, is heated volume sensing, layer 3 porous. According to a preferred embodiment, the upper layer 3 has a structure with a plurality of fold elongated pores 3a in the form of tubes which are substantially parallel.

According to a particularly preferred embodiment, the pores 3a together with the walls 3b between the pores a honeycomb structure.

In other words, the material of the upper layer 3 forms a honeycomb. structure This is illustrated in Figure 3, which shows the honeycomb structure seen from above.

It is preferred that the average inner diameter of the pores 3a ter are Inellan 0.5 and 3 mm, and that their average the mutual distance is between 0.5 and 5 mm. According to a preferred embodiment, substantially all pores 3a have the same shape and dimensions and are spread evenly over the surface of the lower part the layer 2 which is coated with the upper layer 3. p paIranOrXan sokningstexi dog 20080635 10 15 20 25 30 As is clear in Figure 1, the pores 3a extend substantially vertically towards the lining element 1 towards the top of the oven. heated volume facing surface. In addition, the pores 3a are open out towards this surface and thus also towards the heated volume of the oven.

The pore ends facing away from the heated volume of the oven are, å the other side, clogged by the material of the lower layer 2, since the porous upper layer 3 is partially immersed in it lower layer 2, see below.

Figure 2 illustrates, in a manner similar to Figure 1, a lining element 11 according to a second preferred embodiment according to the present invention. The lining element ll contain takes, in a similar manner as described above in connection to Figure 1, a lower layer 12, which suitably has properties such as those described above in connection therewith wonder stored 2.

Parts of the surface of the lower layer l2 which is in operation arranged to face the heated volume of the oven are coated with an upper layer l3, which is made of a material that corresponds to what. described above in connection with the above the layer 3. Like the upper layer 3, the upper is further The layer 13 is porous and includes elongate, parallel pores 13a which are separated by walls 13b. In contrast the upper layer 3 runs the pores 13a in the upper layer 13, however, time substantially parallel to the surface of the lining element ll.

Figure 2 also illustrates how those of the 'pores which, are not arranged in a position immersed in the lower layer 12 are open at both ends. p; »Patranomnsiíkningstext doc 2008-00-25 10 15 20 25 30 It has surprisingly been found that when the surface of the lining elements coated with such a porous material 3, 13 increases the resistance to thermal shock dramatically, both when it applies to rapid heating and rapid cooling. This leads that the elements last longer and that they do not have to be replaced out just as often, saving money and time.

According to a preferred embodiment, the upper layer is 3, 13 between 1 and 5 cm thick.

It is possible to let the porous, upper layer 3, 13 cover all or substantially all of it when operating towards the oven compartment facing the surface of the lower layer 2, 12. According to a preferred In one embodiment, the upper layer 3, 13 covers the greater part of the surface of the lower layer 2, 12.

According to a particularly preferred embodiment, the upper covers the bearing 3, 13 the surface of the lower bearing 2, 12 only in spots.

According to this embodiment, they form of the upper layer 3, 13 covered spots 4b, 14b a regular pattern on the bottom bearing 2, 12 surface. Especially good thermal properties have obtained with lining elements where the covered spots 4b, 14b are isolated from each other by means of narrow, elongated areas 4a, 14a which are not covered. For example the upper, porous layer 3, 13 can be arranged on the lower layer. ret 2, 12 in the form of next to and at a distance and independent spaced apart, square or rectangular units ter.

Thus, when the upper material 3, 13 is arranged that in modules only patch the bottom with material 2, 12 elongated gaps 4a, 14a between the modules 4b, 14b even better resistance to thermal shock is achieved. the reason p 'xpalranor ansokningstextdnc, 2008-06-25 1o_ 15 20 25 30 to this is believed to be that the thermally induced geometric material changes that occur due to the sharp the temperature gradients that arise during operation in the nwdules 4b, 14b into the heated volume of the oven not knowing free ends causes material fatigue to the same extent as is the case when the upper layer 3, 13 is arranged to cover the whole lower layer ret 2, 12.

According to a preferred embodiment, each module 4b, 14b has one maximum, perpendicular to the surface of the element 1 extending, meters of Inellan about 5 and 10 cm. According to a special preferred embodiment are the modules 4b, 14b in the form of dratic units with the dimensions 5 x 5 cm or 10 x 10 cm.

It is further preferred that the width of the gaps 4a, 14a is significantly smaller than the surface dimensions of the modules 4b, 14b.

It will be appreciated that a lining member 1, 11 according to the present invention invention may also include additional layers, in addition to that lower 2, 12 and the upper 3, 13 layer, as long as the surface tersta, towards the heated volume of the oven, the stock is made up of the upper, porous layer 3, 13.

According to the present invention, a lining element is manufactured. ment lq ll according to the present invention by i_ a first step, cast the lower layer 2, 12 to the desired thickness. play. According to a preferred embodiment, the lower layer is cast in such a thickness that the total final length of the element give thickness, including the upper layer 3, 13 and any additional layers, will be between about 30 and 50 cm.

In a second step, the upper layer 3 is then formed, that modules 4b, 13 genome 14b of porous material is lowered a piece in the not yet solidified, cast material as. forms it p mammor ansokxxingstext dos, 2008-06-15 10 15 20 25 30 lower layer 2, 12. The porous material is immersed in it cast the material to such a depth that it partially sticks out above the surface of the cast material, preferably between 5 and 10 cm.

The pore ends that. after immersion are placed under it the surface of the cast material is clogged by the cast material, why arranged perpendicular to the surface of the cast material pores will only have the pore openings that face in open to the heated volume of the oven.

Then, in a third step, the cast material is allowed to solidify. Thus, the modules 4b, 14b of porous are also fixed material in the lower layer 2, 12 and thus forms the upper the bearing 3, 13. The lining element 1, 11 thus formed may be of the type illustrated in principle in Figure 1, with perpendicular porn direction, or of the type in principle illustrated in Figure 2, with parallel porn direction. It is realized that other types of pore geometries can also be used.

According to a preferred embodiment, the modules 4b, 14b are lowered porous material down into the cast material so that they form a regularly recurring pattern with needle spaces 4a, 14a between modules 4b, 14b, in accordance with what has been described OVân.

According to the present invention, the liner of the invention elements 1, 11 can advantageously be used as building elements and / or insulation in an industrial furnace. It is especially preferred to use turn elements of the invention in furnaces operated with one or several DFI burners and / or with one or more oxyfuel burners in the lining of such furnaces in Boot applications. are subject to very severe thermal shocks p ipatranonansokningstextdoc. 2008-06-25 10 15 20 25 30 Operation. A particularly suitable field of application for the invention the lining element l, ll of the ring is in furnaces for continuous DFI heating of metal strip, where the metal strip continuously passed through the oven and past one or more DFI burners. In- lining elements arranged in the vicinity of such a DFI burners are exposed to very strong thermal shocks at Operation.

By using lining elements according to the present invention finding in such an industrial furnace thus achieves that advantage that each element withstands thermal shock better than conventional tional lining elements. This leads to reduced needs of maintenance and replacement of lining elements, which in its luck leads to reduced costs and better availability at the industrial furnace. In addition, contamination problems are avoided of loose fibers from fibrous lining materials. One further advantage is that the pores in the upper layer allow one lower total weight for each lining element, which decreases the total weight of the lining.

Preferred embodiments have been described above. However, is it is obvious to the person skilled in the art that many changes can be made of the described embodiments without departing from the invention. one thought.

For example, other types of pores can be used in the porous the material in the upper layer 3, 13, as insulated or fully or partially interconnected bubbles filled with gas, such as air or an inert gas known per se. In addition, the pores can be elongated but have different porn directions than those illustrated in Figure 1 and Figure 2, respectively. In particular, the pores may have extending directions and / or be combined with bubbles. In this respect, it is essential that the pores be p 'palranor ~ ansókningstevt.doc_ 2008-0635 10 15 20 25 takes up a significant proportion of the total volume of the upper to achieve the benefits of the present invention.

Examples of other useful pore structures, in addition to those above described, parallel and elongated pores, are foamy or fungal structures.

An alternative manufacturing method for lining elements according to the present invention is that in the others described above step, instead of lowering modules of porous material al, instead lowering a plurality of hollow tubes into the cast the material. The pipes may be of a suitable refractory material, wherein the upper layer may be ready when the pipes are allowed fixed in the cast material when it has solidified in it third step. Alternatively, additional refractory material cast, in a separate fourth step, around those in the cast the material fixed the tubes, so that the upper, porous material thus formed.

When such tubes are used to make the upper layer 3, 13, it is preferred that the upper layer 3, 13 be arranged to only patchily cover the surface of the lower layer 2, 12, i in accordance with what has been described above. This can happen on its own conventional way.

Thus, the invention should not be limited by the methods described herein. embodiments, but can be varied within. framework for those attached requirements. p patranorï fl nsokningstexl doc. ZO0S ~ 0 (> - 2 $

Claims (15)

Lining element (l; ll) for an industrial furnace, comprising a first layer (2; l2) of a first refractory material, characterized in that the surface of the lining element the element (l; ll) which is intended to face the heated volume of the furnace is at least partially coated with a second layer (3; l3) of a second refractory material, where the second material is porous. Lining element (l; ll) according to claim 1, characterized in that the second material has (3a; l3a) a v a porous structure where the pores are elongate and parallel. Lining element (l; ll) according to claim 2 (l3a), claim 2, wherein the pores (l; ll) extend parallel to the surface of the lining element. Lining element (l; ll) according to claim 2 (3a), characterized in that the pores extend vertically towards the surface of the lining element (l; ll) and that the pores (3a) are open towards the lining element (l; ll). ) surface. Lining element (l; ll) according to one of Claims 2 to 4, characterized in that the pores (3a; 13a) in cross section together form a honeycomb structure. Lining element (l; ll) according to one of the preceding claims, characterized in that the second layer (3; l3) covers most of the surface of the lining element (l; ll) at the same time as the second layer (l; ll) ( 4b; l4b) is (3; l3) covers the surface of the lining element only in spots, and in that the covered spots are isolated from each other by means of narrow, p \ ~ patranorhansokningsrexl doc. 2008-06-25 10 15 20 25 30 ll elongated areas (4a; a4a) that are not covered by the other material. Lining element (l; ll) according to one of the preceding claims, characterized in that the average inner diameter of the pores (3a; l3a) is between 0.5 and 3 mm. Lining element (l; ll) according to one of the preceding claims, characterized in that the average mutual distance of the pores (3a; l3a) is between 0.5 and 5 mm. Lining element (l; ll) according to one of the preceding claims, characterized in that the second material is between 1 and 5 cm thick. Lining element (l; ll) according to one of the preceding claims, characterized in that the second material is a ceramic material such as Algh. ll. Method for manufacturing a lining element (1; 1l) according to. any of the 'requirements. 10 - 10, characterized in that the first material in a first step is cast to the desired thickness and in that the second material in a second step is immersed in the cast material before it solidifies, to such a depth that the second material partially protrudes from the cast material and that the cast material is then allowed to solidify in a third step. Method according to claim 11, characterized in that the second material is in the form of finished modules (4b; 14b) of porous material and in that the second material in the second step is lowered so that the modules (4b; 14b) form pi 'patranorm search application doc, 3008-06-25 10 15 l2 a regular pattern with spaces between modu- (4b; l4b). (4a; l4a) lerna Use of a lining element (l; ll) according to any one of claims l - 10 in an industrial furnace. l4. Use according to claim 13, characterized in that the industrial furnace comprises a DFI burner. Use according to claim 14, wherein the industrial furnace is intended for continuous DFI heating of metal strips. l6.Use of any kind. of claims l3 - 15, k ä n n e - t e c k n a d a v that the industrial furnace comprises an oxyfuel burner. p '\ paxranov * application taxi doc. IOOQbOO-ZS