EP0290791A1 - Hollow ceramic plug for coke oven doors - Google Patents

Abstract

1. A plug for coke-oven-chamber doors, having a gas-collecting space which is accessible to the gaseous coking products and extends in the longitudinal direction, the plug being hollow in design and having a plurality of openings which are distributed along its length and are located on the side facing the oven chamber, characterized in that the plug is composed of mats (5, 28) gunited with a fire-resistant material.

Description

The invention relates to a stopper for coke oven chamber doors with a gas collection chamber which extends in the longitudinal direction and is accessible to the gaseous coking products, the stopper being hollow and having a plurality of openings distributed over its length, which are located on the side facing the furnace chamber. The coke oven doors are usually provided with plugs made of refractory material, which extend approx. 400 mm into the coke oven chamber and in this way prevent heat losses and inadmissible temperature increases in the iron oven fittings - such as chamber frames, wall protection plates and door bodies. The door bodies are also provided with cutting edges, which seal iron on iron to ensure that the resulting gaseous and vaporous coking products cannot escape into the atmosphere.

The known refractory plugs have a high weight and require correspondingly sturdy door bodies and door lifting devices.

Another problem with conventional stoppers is that they affect the vapor and gaseous coking products. During the coking process, the vaporous and gaseous coking products are taken up by a horizontal gas collecting space, which is formed by the free space above the coking coal, and discharged from the coke oven via a riser pipe. The vapor and gaseous coking products are created in all areas of the furnace batch. The gases generated below must escape through the coking coal. It should be noted here that in the lower area form increased gas pressures in the furnace chamber because the resulting gases have to overcome the resistance of the coal bed in order to reach the horizontal gas collecting space. This excessive gas pressure, which occurs particularly in the first hours of the coking process, leads to gas leaks into the atmosphere at the doors. That means loss of coking products and unwanted emissions.

In the past, therefore, it has been proposed to use door plugs which are box-shaped and made of highly heat-resistant steel to avoid the disadvantages described above. The steel box forms a gas collecting space which extends in the longitudinal direction on the coke oven door and is accessible to the steam or gaseous coking products.

However, testing has shown that the steel box is subject to very strong deformations. Because of these deformations, it was no longer ensured that there was sufficient play between the stopper and the coke oven chamber wall for lifting the door and reinserting the coke oven door.

In the development of door plugs - starting with the box-shaped door plugs - metal door plates have been adopted. The door shields consisted of overlapping sheets of refractory steel. The individual sheets were held on the door body by spacers. This brought about such an extensive improvement that the door plates could be used in practice for the first time. Nevertheless, door plates made of sheet metal are still subject to considerable deformation. In addition, the refractory brittle Steel to a very considerable extent with the duration of operation.

In order to prevent warping when the shields are heated in the coke oven, free expansion must be provided at one end of the individual segments. Due to the expansion of all plates or sheets in the same direction, mainly downwards, there is no fixed installation dimension in the cold state, which leads to difficulties in the design. It has therefore been proposed to direct the expansion of the lowermost plate in the opposite direction, that is to say upwards, in order to also avoid damage to the furnace sole or the chamber frame. Despite these measures, faults have so far not been completely excluded. One reason for this can also be seen in the fact that, due to a necessary gap between the shield and the furnace wall, coal enters the space between the shield and the door body during filling and can push the shield forward. This coal is also not fully cooked and leads to considerable emissions when the door is pulled off. By means of fixing devices with lateral guidance of the door when inserting different gap widths to the two walls of the coke oven can be largely avoided, the distances must be relatively large (approx. 20 mm) due to the high thermal expansion of the steel. In addition, a high-temperature steel is to be used with these metallic shields, which is correspondingly expensive.

Nevertheless, this steel also suffers considerable scaling due to air access when the door is lifted. To avoid the disadvantages of metallic shields, shields made of ceramic plates have been proposed. In order to achieve sufficient mechanical strength, these plates are supplied very thick and only sufficiently stable in smaller dimensions. The ceramic shields are therefore much heavier than metal shields (factor 1.5 - 2.0). Another major problem is the mounting and connection of the ceramic shields on the door body. Here, the different coefficients of expansion of the two different materials have a disadvantageous effect. The ceramic shields experience cracks at this point, so that their mounting tabs loosen more.

The invention has for its object to eliminate the disadvantages of previous shield constructions. The invention resumes with the box-shaped door plug, the development of which has been stopped for the reasons explained.

According to the invention, instead of the steel for the hollow plug, mats are used which are door-locked with refractory material. As mats, conventional structural steel mats, e.g. B. plug-in metal mats or expanded metal mats, preferably made of fine-grained structural steels, or asbestos fabrics or replacement fabrics such as ceramic fibers can be used. The mats can easily be subjected to any desired shape. Bends or kink and arch shapes are easy to manufacture. The goal locking on these carrier mats is preferably carried out in negative forms. In this way, in contrast to conventional ceramic plates, a better stiffness of the plug body can be achieved without increasing the weight. The mats formed in this way are then goal-locked on both sides. In the first stage of goal locking, a porous sprayed on ceramic material that allows larger strains of the carrier material than the own stretch. In this way it is prevented that the applied spray compound survives without damage at operating temperatures. In the second step, a tightly closing refractory mass is used, which for better networking and adhesion with long-fiber material, eg. B. is enriched with asbestos or its replacement materials. The entire coating can be limited to 2-3 cm on each side of the mat, which increases the elasticity of the plug body and reduces its susceptibility to breakage. Refractory molding compounds with good adhesion to structural steel mats and whose thermal behavior largely adapt to the metallic support structure are available.

The stopper body is preferably designed as a basket which is closed at the top and which can be clamped directly onto the door leaf. In order to reduce the gas pressure on the sealing elements of the coke oven door as far as possible, side slots can be made in which their protected position largely prevents the penetration of coal.

• 1. Für die hohen Temperaturen steht ein geeigneter feuerfester Baukörper mit metallischem Stützgerüst zur Verfügung.
• 2. Der Baukörper kann in jeder gewünschten Größe ausgeführt werden, d. h. der Stopfen bzw. das Schild besteht nur aus einem Segment.
• 3. Der Baukörper kann vor der Beschichtung leicht jeder gewünschten geometrischen Form angepaßt werden. Die Biegesteifigkeit wird auf diese Weise ohne Gewichtserhöhung verbessert.
• 4. Wird er als unten offener Korb ausgebildet, so kann das Eindringen von Kohle in den Innenraum weitgehend verhindert werden.
• 5. Beschädigungen beim Ein- und Aussetzen der Türen und der Türrahmen können mit dieser Konstruktion wesentlich reduziert werden.
• 6. Zum Abbau des Gasdruckes können seitlich groß­flächige Schlitze problemlos eingebracht werden.
• 7. Der Stopfen kann durch einfache Klemmvorrichtungen direkt am Türblatt befestigt werden; aufwendige und anfällige Abstandshalter, die zur Aufnahme der schweren keramischen Platten entsprechend stabil ausgeführt werden müssen, können entfallen.
• 8. Die Konstruktion ist viel leichter als alle anderen derzeit praktizierten Lösungen, das Ballastgewicht wird einschl. der sonst erforder­lichen Abstandshalter um etwa den Faktor 2 minimiert.
• 9. Die Konstruktion kann auch in der Anheizphase einer Batterie ohne nachteilige Auswirkungen verwendet werden.
• 10. Reparaturen sind leicht möglich, ohne den ganzen Baukörper verwerfen zu müssen. Sie können außerdem problemlos durch Aufspritzen neuer Feuerzementmassen in kurzer Zeit vor Ort erledigt werden.

If small amounts of coal should nevertheless penetrate, they can be discharged through the open shape of the plug. A sufficient undercut to reduce the gas pressure is also possible. In addition, the interior of the plug for better insulation of the door body and the closure devices can be foamed with cera fibers. This insulation material increases the weight of the plug only insignificantly, but has an excellent insulation effect. This plug or shield design according to the invention fulfills all procedural requirements and includes the following essential advantages:

• 1. A suitable refractory structure with a metallic support structure is available for the high temperatures.
• 2. The structure can be made in any desired size, ie the plug or the shield consists of only one segment.
• 3. The structure can be easily adapted to any desired geometric shape before coating. The bending stiffness is improved in this way without increasing the weight.
• 4. If it is designed as a basket open at the bottom, the penetration of coal into the interior can be largely prevented.
• 5. Damage when inserting and removing doors and door frames can be significantly reduced with this construction.
• 6. To reduce the gas pressure, large slits can be made on the side without any problems.
• 7. The stopper can be attached directly to the door leaf using simple clamping devices; elaborate and fragile spacers, which have to be made stable to accommodate the heavy ceramic plates, can be omitted.
• 8. The construction is much lighter than all other currently practiced solutions, the ballast weight including the otherwise required spacers is minimized by a factor of 2.
• 9. The construction can also be used in the heating phase of a battery without any adverse effects.
• 10. Repairs are easily possible without having to discard the entire structure. They can also be easily done on site by spraying new refractory cement.

Various exemplary embodiments of the invention are shown in the drawing.

In Figures 1 and 2, the furnace chamber is 1, the furnace walls are 2 and the door body is designated 3. The door body 3 has a sheet pile profile and is flexible in itself. It is part of the well-known Becker door, in which a sealing element in the form of the sheet pile and a force transmission element in the form of a profile frame are separated from one another. The profile frame functioning as a power transmission unit interacts with the usual locking devices. Its force is transmitted in the area of the sealing surfaces of the door body by means of a large number of screws which are attached all the way round and evenly spaced.

According to FIG. 1, a plug 4 with a U-shaped cross section interacts with the door body 3. The stopper 4 is designed as a hollow body and has been produced from fine-grain structural steel with the aid of a structural steel mat. In the exemplary embodiment, the structural steel mat has a wire thickness of 3 mm and a mesh size of 100 mm. It is shown in dashed lines in FIG. 1 and labeled 5. The structural steel mat is made of refractory concrete goal-locked. The goal locking was done in one form. The goal locking is done in two sections. In a first process step, the structural steel mat 5 is embedded in a porous refractory concrete. In the second stage of the process, the application of a dense refractory concrete is provided. The dense refractory concrete is provided with relatively long asbestos fibers or ceramic fibers for better bonding.

The second coating takes place after the preliminary product has been removed with the structural steel mat 5 and porous refractory concrete from the negative mold. As a result, the applied first layer of porous refractory concrete is accessible from both sides. The refractory layer made of refractory concrete is designated by 6 in FIG.

According to Figure 1, the plug 4 is undercut on the sides 7 and 8, so that there are gas channels.

The stopper 4 has a U-shape in cross-section, the ends of the free legs being angled outward so that they can be held on the door body 3 with sheets or webs 9.

According to FIG. 1, the metal sheets 9 are provided all round on the door body 3 and carry the door seal 10. With the door seal 10, the door 3 lies against the chamber frame of the coke oven, which is not shown in detail.

Figure 2 shows a plug 15, which differs from the plug 4 in that it has no undercut on the side walls 16 and 17. Furthermore, the bends or collars of the stopper 15 denoted by 18 are held on the door body 3 by means of angle profiles 19. The angle profiles 19 also form the Sealing surfaces of the coke oven door with the chamber frame of the coke oven not shown in detail.

Figure 3 shows a section along the center line 20 in Figure 2. In this section it is clear that the plug 15 is open at the top and bottom. The opening at the top is used for the free extraction of the penetrating coke oven gases. The opening at the lower end should allow coal to fall out when the door is lifted.

Furthermore, slots 21 are shown on the walls 16 and 17 in FIG. The slots 21 serve the entry of coke oven gas into the interior of the stopper 15, which forms a vertical gas collecting space.

The slots 21 run obliquely.

FIGS. 4 to 9 show a further embodiment with a plug 25 which is closed at 26 at the top and also has a rear wall 27. The plug 25 has a multilayer structure corresponding to the plugs 4 and 15, the enclosed mat being designated 28, the porous refractory layer 29 and the two outer sealing refractory concrete layers 30 and 31.

The closed rear front is provided with openings 32 and 33, which serve for the escape of coke oven gas. In addition, the rear front 27 has hooks 34 with which the stopper 25 can be hung in the holding claws 35 of the door body denoted by 36. The embodiment according to FIGS. 6 and 7 differs from that according to FIGS. 8 and 9 in that, according to FIG. 6, 35 side plates 37 on the holding claws are provided, which secure the hook 34 against lateral displacement. The sheets 37 can also be attached to the hook 34.

According to FIGS. 8 and 9, the sheets 38 are provided. The sheets 38 are attached to the hook 34 and extend beyond the claws 35 so that the plug 25 can be secured with bolts 39.

The rear wall 27 in the embodiment according to FIGS. 4 to 9 has an insulating effect. It protects the furnace body from heat radiation from the coke-side plug part. An insulation layer 40 is part of the structure of the rear wall.

Claims (5)

1. Plug for coke oven chamber doors, with a longitudinally extending and for the gaseous coking products accessible gas collection space, the plug being hollow and having several openings distributed over its length, which are located on the side facing the furnace chamber, characterized in that the plug consists of mats (5, 28) which are gate-locked with refractory material. 2. Plug according to claim 1, characterized in that the mats consist of plug-in metal or expanded metal and / or fine-grain structural steels or asbestos fabrics or ceramic fabrics. 3. Stopper according to claim 1 or 2, characterized by a multilayer door lock, wherein the mat (5, 28) is surrounded by a porous layer and the outer layer is formed by a dense layer. 4. Stopper according to one or more of claims 1 to 3, characterized by the enrichment of the door locking layer with fiber material. 5. Stopper according to one or more of claims 1 to 4, characterized by refractory concrete as a gate locking material.

Images