DE3440311C2 - - Google Patents

Description

The invention relates to a coke oven door for a horizontal chamber coking furnace with a heat protection Protection protruding into the furnace chamber and connected to the door body shield over which the furnace filling is at a certain distance from the Door body is held, the door body during the coking operation with at least one locking device against the Door frame of the oven is pressed.

Such coke oven doors are under also included in the older proposal P 33 27 337.5. This Proposal is for a new type of door body training with the associated sealing device directed. The new door body is characterized in particular by lightweight construction, price advantages over conventional doors and through a high, permanent sealing effect out. According to P 33 27 337.5, the new door body is partly included conventional fireproof door plugs combined.

From German patent specification 2 38 363 is also a Door for coke ovens with adjustable on the back wall Protective shield known, the protective shield by articulated Intermediate links are connected to the back of the door and themselves can move towards the door. The should by articulated Intermediate links protective shield connected to the back of the door by an adjusting device from the outside in its respective position be lockable. After the presentation of the embodiments This patent is the protective shield as a flat, one-piece Plate with rear stiffening ribs.

With such a coke oven door with level, over the door height extending one-piece plate, it has been shown that at metallic version of this protective shield has not yet been used sore difficulties occur. It is particularly striking severe deformation of the one-piece protective shield. As a result of one large temperature gradient of the coke-side shield surface against There is an over the protective body surface on the door body side very strong curvature.  

At the time of filing the German patent 2 38 363 the usual heights of coke ovens 1.5 to 2 m. With such a small one Door heights, the total deformation of the protective shield is possible still in the tolerance range. With today's coke oven heights of 4 m, 6 m and in the future 8 m and more, the total ver Formation of the protective shield either lead to between the oven sole and protective shield and between protective shield and chamber walls such openings occur that coal in excess between protection shield and door body penetrate. This effect would be drier Coking coal, especially preheated coal, is still very important intensified.

More recently, the idea of a metallic protective shield been picked up again. There are two possible solutions been taken.

The US patent is an example of one solution 40 86 145. It tries to correct the faults by one intensive connection and support of the protective shield on the furnace body counteract. Intensive means here: The protective shield is over ver at least one over the entire length of the protective shield running web connected to the door body. In an execution form support rods are provided on both sides of the web. In a another embodiment are two spaced apart Bridges provided, which are additionally ver by side ribs are stiff. However, this approach has primarily thermal engineering Disadvantages by contact heat through the webs, ribs and Support rods are passed into the door body. The Associated Heating the door body easily leads to undesirable leaks.

An example of the other approach taken is the German Offenlegungsschrift 31 05 703. There is a protective shield shown, which is built like a scale, d. H. from a variety there are smaller, overlapping individual parts. Every single part  is attached separately. The smaller parts are subject a percentage of the same total thermal expansion as a one-piece Protective shield. The absolute measure of thermal expansion of every single part however, is much less than that of one-piece protection shield. By individual suspension of the various individual parts and The overlapping arrangement of the individual parts affects the heat deformation of each individual part is not excessive on the others Individual parts. The total heat deformation is kept in a portable range Limits.

The invention proceeds while maintaining a one-piece Shield another way. The invention proceeds from the following considerations: Operating difficulties can arise in the Set the raw gas duct between the door body and the protective shield. The is attributed to the fact that the raw gas channel in such doors is totally expanded and the resulting gas pressure depending on Original pressure on the coke oven battery more or less after a short cooking time, averaged over the door height of positive to negative values d. H. from original Upper pressure then creates negative pressure. This creates suction. At insufficiently coke oven doors inevitably lead to this phenomenon commonly used to draw atmospheric air between the chamber frame and the door body. The air penetrates into the raw gas duct and causes, among other things, the following faults:

The aggressiveness of oxygen can make it creeping Destruction occurs on the hot brickwork of the furnace chamber; at The metal coke oven door can be severely leaky Protective shield with its fastenings on the door body for melting or to be destroyed. The effect would be comparable to one Flame welding.

According to the invention, operational difficulties are also solved existing temperature differences seen. It is assumed that the resulting raw gas temperatures in the total expanded  Raw gas duct over the distances between both the protective shield and the door body as well as between the chamber walls at approx. 500 to 700 ° C each according to the state of cooking and driving style of the coke oven.

At coke temperatures of around 1100 ° C there is a temperature jump from the protective shield to the raw gas duct of approx. 400 to 600 ° C. This phenomenon inevitably leads to an influence on the elongation or excessive tensions between the relatively cold wall plant in the area of the raw gas channel and the relatively hot coal touched masonry or relatively cold stove frame. Are from it incalculable wall damage in the area of the masonry expect. Furthermore, the gas permeability in the stone material increases the low wall temperatures considerably, with the upper surface structure of the stone material increasingly with the term of the Coke oven changes negatively and tends to flake and crack.

The invention also assumes that one with no coke coal-filled coke oven or a protruding coke oven (the coke pressing has been delayed) the protective shield used heats up so quickly in a short time that increased heat radiation over the protective shield unhindered both on the door body and also acts on the chamber frame. The effect of heat leads to uncontrolled deformations on the one hand on conventionally cast Door body (thereby causing door leakage) to the other on the chamber frame. Due to the increased pressure on the chamber frame stepping chamber frame bend the frame joint between masonry and chamber frame free. A so-called frame joints are created leakage.

Finally, the invention takes into account the fact that, at the usual coke oven temperatures, the protective shield explained at the outset tends to warp continuously over the coke oven height due to its geometry as a flat, one-piece surface. This causes the already explained risk that when a coke oven door is inserted or removed, the protective shield will cling to the oven walls and be torn off. The consequences are also damage to the furnace walls. Furthermore, the distortions of the shield that occur increase the opening width of the two gaps between the shield and the coke oven walls. This increases the amount of unwanted coal in the raw gas channel. With low water contents (less than 10% by weight H ₂ O) of the input coal mixture, the coal accumulation in the expanded raw gas channel is particularly large. There, the coal leads to disadvantages of the uncontrolled condensate formation in the area of the door seal because of the low head temperatures or forms a semi-coke plug of different heights, which must be removed manually and time-consuming after each furnace run by the operator.

According to the invention, all of these difficulties are overcome keeping a one-piece, extending over the door height Protective shield avoided by placing between the protective shield and the Door body arranged at least one other similar shield is.

It is known from DE-OS 33 44 976, the door body on the coke side to be provided with insulation and the insulation in the protective box to arrange. However, the insulation and the protective box do not form one same shield as the coke-side shield.

The one additional shield creates two raw gas channels, that as an inner, coke-side raw gas channel and as an outer, door body-side raw gas channel can be called. With several additional shields result in more raw gas channels.

With the help of the inner and outer raw gas duct, the raw gas extraction quantity can be controlled or evened out in such a way that the raw gas pressure at the sealing surface between the coke oven door and Chamber frame is optimized in the measurable positive range.

The heat radiation of the door body to the outside is reduced by the protective shield facing the door body acts as a crane. Choice are wise between the coke-side protective shield and the door body additional protective shields (ecranes) are also arranged. Next A saving of insulating material on the door body is particularly important due to the ecranization effect in case of protruding or empty standing coke ovens the resulting high heat radiation from  Door body and kept away from the chamber frame. The ecranization effect provides an even drop in temperature along the masonry starting from the coal or coke-touching protective shield in the direction Door body safe.

Compared to the well-known, flat and one-piece protective shields made of heat-resistant metallic material in the usual high coke oven temperatures a much greater dimensional stability. One reason for this is the low temperature gradient on the coke side protective shield due to the thin-walled protective shield, on the other hand the special profiling of the protective shield. in the the other protective shield of deformation and off acts bulge of the protective shield on the coke side. This allows the wall thicknesses of the protective shields according to the invention considerably be made thinner than known protective shields. That has two Significant advantages: Firstly, this reduces the Temperature gradients, second are the protections according to the invention shields with sufficient dimensional stability overall lighter than the be knew protective shields.

The connection of the same protection is particularly advantageous shield. According to the invention, these are then preferably mirrors arranged symmetrically. This gives the protective shields additional Dimensional stability. A possible deformation and bulge of the The protective shield on the coke side acts as protection on the door body Significantly counter. According to the Er Cross-sectional geometries with different resistance moments selected. This means that the protective shield on the door body side has a greater resistance to deformation directed away from the coke moment as in the opposite direction. This will make the Restoring forces of the additional protective shield an additional Effect.

As a result of the mirror-symmetrical design of the protective shields can protect the coke-side shield against damage the door body-side protective shield can be replaced and vice versa.  

Optionally, different profiles are combined with each other kidney. This can be used to reduce the moment of resistance of the to increase the protective shield on the door body.

Because of the lightweight construction and easy manufacture the shield construction are the protective shields according to the invention overall less expensive than other known protective shields.

By using cross-sectional profiles for the protective shields, the profiles of standard steel sheet piling or lightweight profiles or panel profiles can further reduce costs be effected.

According to the invention, the protective shields have proven to be favorable over their entire height parallel to each other or inclined to each other to arrange. If the arrangement is inclined, the coke-side protection shield in turn arranged vertically, so that in itself only the door body-side shield is inclined. With the inclined arrangement can the different gas pressure in the gas discharge duct is taken into account will. According to the invention, the inclination is chosen so that per running meter of furnace height a pressure loss of 1 mm water column is balanced.

In addition, in particular the distance between the protection shield by interchangeable, even across the height of the Protective shields distributed spacers can be made changeable. Depending on the operational conditions, this may also result the gas discharge amounts in the gas discharge duct between the two guards shields are regulated. Likewise, by distance Change the protective shields to the door body at its temperature exert influence, d. H. by appropriate distance can have a certain desired or allowable body temperature be ensured. On the other hand, with the same  Distance of the shields from each other the total distance from the door change body, in the same or opposite sense. This allows the flow conditions in both gas discharge channels be optimized.

To seal the gap between the protective shields and the adjacent chamber walls it is convenient on the sides of the two Protective shields to attach at least one sealing plate, which lies against the chamber walls when the protective shields are lowered. There can special sealing plates with obliquely rising oblong holes be used by the bolts or spacers between the are passed through both protective shields. To simplify the The sealing plates can be installed and replaced from the side provided with open slots towards the middle of the chamber and have Attach bolts or spacers.

For a correct insertion of the coke oven according to the invention door, it is advantageous if the sealing plates are in the raised position the protective shields stood sideways in the elongated holes or slots are moved inwards; d. H. sunk between the shields are. The sealing plates then move when the protection is put on shields outwards against the chamber walls. That happens for example shows that the sealing plates below between the protective shields protrude or with a suitable foot or pestle or the like are provided, the shape of the profiles when putting on the protection shields forces itself due to the guidance in the oblique slots or to move elongated holes outwards towards the chamber wall. The To put the sealing strips causes an advantageous seal between the protective shields and chamber walls.

The sealing plates are on the side of their contact surface with the Chamber walls bent or folded. In a horizontal cut a sealing plate results in an S-shaped or Z-shaped or angular cross-section. The beveled or  bent leg of this cross section provides a gentle Safe contact with the chamber walls and gives the sealing plates at the same time excellent dimensional stability in the longitudinal direction.

Finally, it is advantageous to arrange the sealing plates close to the protective shield on the door body side. This allows the raw gas to flow unhindered through the gap between the protective shield on the coke side and the chamber walls into the inner raw gas channel. The inflow into the outer gas discharge duct is opposed, however, so that the seal between the door body and the chamber frame is additionally relieved. The invention is explained in more detail with reference to the accompanying FIGS. 1 to 7 in exemplary embodiments.

Fig. 1 shows a horizontal section through the door inserted according to the invention in a chamber opening.

Fig. 2 shows a vertical section through part of the door according to the invention.

Fig. 3 shows a number of protective shields that can be used according to the invention in cross section.

FIGS. 4 and 5 show in vertical section, the coke oven door with different distances between the shields.

Fig. 6 shows a detail of the protective shields with sealing plates in the raised and lowered state in the coke oven chamber.

1 Fig. 7 shows as Fig. Shows a horizontal section through another embodiment of the coke oven door according to the invention.

In the figures, the furnace chamber with the associated heating or chamber walls is indicated by 1 . Around the vertical opening of the furnace chamber 1 runs the door frame 7 , on which the sealing member 6 rests against an inserted coke oven door. The coke oven door, as described for example in German patent application P 33 27 337.5, consists of a door body with a power transmission unit and a sealing unit. The power transmission unit runs as a hollow profile along the door frame and is connected to the door frame at least via a locking device. The locking device is designed as a spring lock. This includes locking hooks on the door frame 7 and pivoting locking bars on the door body, which act on the door body 7 via springs or power pistons. The sealing unit has a sealing plate 5 , which is pressed against the door frame on the circumference of the door frame by means of many evenly distributed and spring-mounted screws 4 . With 5 a is a cover that serves the insulation. To improve the thermal insulation towards the outside, the sealing plate 5 can be designed as a hollow profile, the hollow profile being filled with insulating material 5 b . The sealing plate can be provided with a one-sided bulge according to FIGS. 1 and 7 to the outside. On the inside of the sealing plate 5 , angle irons are attached distributed over the height, of which angle irons 15 are screwed with screws 16 to further angle irons 14 , which in turn are connected to a shaped profile 9 as an external protective shield. The connection between the shaped profile 9 and the angle iron 14 is made by hanging the shaped profile 9 with suitable hooks 9 a on the angle iron 14 .

Instead of the angle iron 15 , flanges or other profiles or screws can also be used. Another shape profile is attached to the shape profile 9 in mirror image as a protective shield by means of bolts 13 with spacers. In Figs. 1 and 2, the positions of the mold are profile at a greater distance from each other, shown at 18, 19 in dotted form. In Figs. 4 and 5, the difference between a smaller and a greater distance of the shaped profiles is also made clear from each other.

In the exemplary embodiment, the distance of the inner protective shield 8 from the sealing surface between the door body and the door frame Z is 400 mm. The distance between the two protective shields is 120 mm. This corresponds to the usual stone plug depth. In practice, depending on the mode of operation of the coke oven, the ratio of the distance between the two protective shields 8 and 9 to the distance between the outer protective shield 9 and the sealing surface between the door body and the door frame 7 is between 1: 1 and 1:10, preferably between 1: 3 and 1 : 5.

In Fig. 3 a number of possible cross-sections are shown for the shaped profiles. The shaped profiles can be rolled in one piece and / or folded and / or bent, or can be composed of several parts. The parts can be screwed or welded. In the simplest case, the shaped profiles are designed as smooth sheets. The cross sections according to FIG. 3 are advantageous . According to FIG. 1, the shaped profiles are laterally connected to one another in cross section and have bulges in the middle between the connection points, the reverse is true according to FIG. 3.1. The shape profiles according to have 3.1 Fig. In the middle of a ge rings spacing and shape profiles are connected there via the bolt 13 with each other, while having the outside to the chamber walls towards a greater distance. The protective shields then again run parallel to each other on the outside. The protective shields can also be curved in the form of a circular arc towards the chamber walls or angularly bent outwards according to FIG. 3.5.

According to Fig. 3.7, the ends are first curved outward in a circular arc and then again inwardly semicircular, so that the ends are directed towards one another. Figs. 3.1 to 3.4 ent also hold different average protrusions formed outward triangular, semicircular or trapezoidal similar to that of.

All shields of FIG. 3 can be used together. Ie it can be z. B. combine the shape profile 8 of FIG. 3.1 with the shape profile 9 of FIG. 3.2. This preferably serves to increase the section modulus of the shield construction.

Finally, FIGS . 6 and 7 show additional sealing plates 24 which are provided with elongated holes 25 . In the exemplary embodiments, only one row of sealing plates is provided between the two shaped profiles 8 and 9 . Instead of one row, however, several rows of sealing plates can also be arranged one behind the other between the shaped profiles 8 and 9 , or can be distributed over a plurality of shaped profiles arranged one behind the other.

Sealing sheets 24 are as close as possible to the outer molded profile 9 in order to prevent gas from entering the outer raw gas channel between the molded profile 9 and the door body and to relieve the sealing member 6 .

In FIG. 6 in the left half of elevated state of the mold sections is shown. The sealing plate 24 has moved away from the chamber wall 2 in the raised state or has been pressed inwards and downwards by a plunger 26 . It protrudes below the shape profile.

On the right, lowered state of the shaped profiles are the protective shields and sealing plates 24 on the furnace bottom and the sealing plate has leant to the chamber wall 2 24th The sealing sheet movement is up to 60 mm compared to the shaped profiles 8 and 9 . The gap between the shaped profiles 8 and 9 and the chamber wall 2 is up to 20 mm in the exemplary embodiment, depending on the width of the coke oven chamber. For example, a 15 mm gap is provided for an average chamber width of 45 cm.

From Fig. 7 the S-shaped shape of the sealing plate 24 can be seen, the sealing plates abut the inside of the outer molded profile 9 and the outside between the molded profile 8 and the sealing plates, a vertical gap for the gas passage remains.

Claims (21)

1. Coke oven door for a horizontal chamber coking oven with a protective shield that also serves as heat protection and protrudes into the oven chamber and is connected to the door body, by means of which the oven filling is held at a certain distance from the door body, the door body being locked with a locking device during the coking process the door frame of the furnace is pressed, and wherein at least one insulation is provided between the protective shield and the door body, characterized in that the insulation is a similar shield. 2. Coke oven door according to claim 1, characterized in that between the protective shield and another shield on the sides of the Shields open gas channel runs. 3. Coke oven door according to claim 1 or 2, characterized in that the protective shield and / or the further shield consists of shaped profiles ( 8 , 9 ) extending over the door length. 4. coke oven door according to claim 3, characterized in that the shaped profiles ( 8 , 9 ) are the same and / or can be used with other shaped profiles. 5. coke oven door according to one or more of claims 1 to 4, characterized in that the shaped profiles with the same Aus formation and parallel arrangement symmetrical to the one in between lying central plane are arranged. 6. coke oven door according to one or more claims 1 to 5, characterized in that the shaped profiles ( 8 , 9 ) have the profile of steel sheet piling or light profiles or panel profiles of steel construction for civil engineering. 7. coke oven door according to one or more of claims 1 to 6, characterized in that the shaped profiles ( 8 , 9 ) are arranged parallel to one another over the entire height of the protective shield or are inclined towards one another, with the coke-side in the inclined arrangement The sign in turn is vertical. 8. coke oven door according to one or more of claims 1 to 7, characterized in that the distance between the shaped profiles ( 8 , 9 ) is variable. 9. coke oven door according to claim 8, characterized in that the shaped profiles ( 8 , 9 ) for changing the distance with interchangeable, evenly distributed over the height of the shaped profiles ( 8 , 9 ) from standoffs ( 12 ) are provided. 10. coke oven door according to one or more of claims 1 to 9, characterized in that the distances between the door body and the central shape profile ( 9 ) on the one hand and the middle shape profile ( 9 ) and the coke oven-side shape profile ( 8 ) on the other hand can be changed differently. 11. Coke oven door according to claim 13, characterized in that the distance of the coke-side molded profile ( 8 ) to the central molded profile ( 9 ) on the one hand to the distance of the central molded profile ( 8 ) to the sealing surface of the chamber frame with the door body on the other hand in a ratio between 1: 1 to 1 : 10, preferably 1: 3 and 1: 5. 12. Coke oven door according to one or more of claims 1 to 11, characterized in that between the shaped profiles ( 8 , 9 ) and the adjacent chamber walls ( 2 ) on the sides of the shaped profiles ( 8 , 9 ) sealing plates ( 24 ) are movably attached , which lie on the chamber walls ( 2 ) when lowering the shaped profiles ( 8 , 9 ) and leave the gas channel open on the coke side. 13. Coke oven door according to claim 12, characterized in that a plurality of sealing plates ( 24 ) are arranged one behind the other. 14. Coke oven door according to claim 13, characterized in that the sealing plates ( 24 ) are provided with obliquely rising elongated holes ( 25 ) through which bolts ( 13 ) and / or spacers ( 12 ) for the two shaped profiles ( 8 , 9 ) are passed . 15. coke oven door according to claim 14, characterized in that the sealing plates ( 24 ) have laterally towards the middle of the chamber open slots. 16. Coke oven door according to one or more claims 14 or 15, characterized in that the sealing plates ( 24 ) in the raised state of the shaped profiles ( 8 , 9 ) protrude from their lower edge and when lowering the shaped profiles ( 8 , 9 ) against them Move upwards and sideways against the chamber walls ( 2 ). 17. Coke oven door according to one or more of claims 13 to 16, characterized in that plungers ( 26 ) which act vertically on the upper edge of the protective shield and with which the sealing plates ( 24 ) are lifted from the chamber walls when the shaped profiles ( 8 , 9 ) are lifted ( 2 ) be pushed away to the middle of the chamber. 18. Coke oven door according to one or more of claims 13 to 17, characterized in that the sealing plates ( 24 ) on their vertical right longitudinal edges have a profile, preferably a bend order. 19. Coke oven door according to claim 18, characterized in that the sealing plates ( 24 ) are S-shaped. 20. Coke oven door according to claim 19, characterized in that the sealing plates ( 24 ) bear against the middle shaped profiles ( 9 ). 21. Coke oven door according to one or more of claims 13 to 20, characterized in that the sealing plates ( 24 ) consist of several sections in the vertical direction.