DE1081413B - Regenerative coke oven battery - Google Patents

Description

Regenerative coke oven battery The invention relates to a regenerative coke oven battery in which the substructure in the area of the bottom channels and the lower part of the regenerators up to a temperature range of about 650 ° C are made of clay-bound building material and the overlying part of the regenerators and the superstructure are made of silica building material.

With coke oven batteries, where the temperature range is lower lying substructure made of clay-bound and the one lying in the area of higher temperatures The superstructure consists of silica building material, is a special auxiliary anchorage for holding together of the kiln masonry required for both components. In particular, it prepares the anchoring the anchor stand in the connecting plane of the two components as a result of the stronger Stretching of the silica building material on the less stretching clay-bound building material Difficulties.

In the case of kiln masonry made entirely of silica building material, one has so far the anchor stands from the furnace ceiling down to the non-refractory Building material carried out existing furnace support plate and all of the lower and upper End of the anchor stand, the tie rods from one furnace battery side to the other pulled through to keep the masonry under tension. Anchoring the anchor stand at the lower end, however, is unfavorable in that the anchoring between the Regeneratorsohlkanäle must be made in which the-Umstellorgane for the combustion media or exhaust gases flowing into or out of the regenerators and there is only little space available for this.

In the case of coke oven batteries consisting of a uniform silica building material with anchor stands running through the entire height of the refractory building material there is also a sagging of the anchor posts in the area below the furnace base, because the thermal expansion of the silica building material is approximately the same as the average height of the regenerators is essentially the same or only slightly different up to the furnace roof. Below In this area, however, the temperatures in the regenerators are so low that that the elongation of the kiln brickwork remains. The anchor stands must therefore be designed in this way or such intermediate layers must be between them and the furnace masonry be attached that the different thermal expansions are taken into account and an even fit of the anchor stands over the entire height is achieved.

According to the invention, the existing clay-bound building material is now Part of the substructure held in tension by being within supports lies, -which are made of the same material as the furnace support plate and through Reinforcements are connected to this, with the Abstützingen also adjustable Anchor supports form abutments for the vertical anchor stands.

With such a design of a regenerative coke oven battery it is achieved that the vertical armature stands, which are now in the area of an essentially uniform expansion, are not subject to any significant deflection after the oven battery has been heated up. Furthermore, no special nachst ellbare anchoring is required for holding the clay-bound substructure, since the expansion of the clay-bound building material on the furnace support plate, for example a concrete slab, is practically the same as the expansion of the material of the furnace support plate. The tied masonry expands - therefore at the same time as the concrete slab - and the supports firmly connected to the concrete slab along the sides of the furnace battery, with a somewhat greater expansion of the totigebound masonry compared to the concrete slab through between the supports and the clay-bound masonry arranged compliant material can be compensated.

Such a Koksofenb? Ltterie also has the advantage that not only saves the tie rods that go through the substructure from one side to the other but also good accessibility to the lower anchoring points and the changeover organs now lying outside the area of the anchoring points. is available.

The invention also is to provide the clay-bonded bricks of the substructure with interlocking tongues and grooves and to arrange the stones enabling at the junction between the clay-bound and Silikamauerwerk with smooth surfaces with the interposition of a displacement of the Silikamauerwerks to Z> el the clay-bound masonry lubricants successive .

The invention is illustrated as an example in the drawings.

Fig. 1 shows the invention in a cross section through an oven battery; -Fig. 2 shows a senkre - Want partial longitudinal section through the lower part of the oven battery according to FIG. 1; Fig. 3 shows a partial vertical cross-section through an oven battery corresponding to Fig. 1; Fig. 4 is a partial vertical 0 i uerschnitt through the lower part of an oven battery in an enlarged scale; Fig. 5 finally shows the clay-bound substructure with the furnace support plate in perspective in a cutout.

The coke oven battery consists of a number of coking chambers 10 with heating walls 11 arranged between them. The heating walls 11 are divided in the usual way by transverse walls 8 into vertical heating flues 12, which are exposed to a flame in groups of, for example, four heating flues and two end heating flues each. each group of heating flues is connected to a corresponding group of heating flues of the other heating wall adjacent to the furnace chamber by a bypass channel 13 which is guided over the furnace ceiling.

- The heating flues 12 are connected at the bottom to the regenerator 16 through ducts 15 °. The regenerators are all used to preheat the combustion air when using high-gas heating. In the case of lean gas heating, one of the regenerators is used to preheat air and the next one to preheat full weak-as. Combustion air or lean gas is fed in from the furnace battery 41 through floor ducts 7 arranged below the regenerators 16. The bottom channels 7 are above a furnace support plate 20 made of concrete. Lean gas is the associated Sohlkanälen 7 fed by a respective change-over mechanism 18 fully a common lean gas line 17 and air through each an adjacent change-over mechanism, not shown.

In the case of star gas heating, the high gas is fed to the heating flues 12 through vertical high gas ducts 19 penetrating through the regenerator walls 21. The gas is fed to the heavy gas channels 19 from a distribution line 22 common to each heating wall through pipes 29. The distribution lines 22 are connected via a connecting line 23 to a collecting line 24 which is routed along the furnace battery and which is arranged in a walk-on foundation space 25 .

Each two high-gas ducts 19 of a heating wall are connected to one another at their lower ends by ducts 66 and to two corresponding high- gas ducts of the adjacent heating wall that work together via the bypass duct 13 by a circulating duct 28. The circulation channels 28 are arranged in the furnace support plate and lined with a refractory building material 37.

The Starkgasr-ear 29 opens by means of a control element configured as a nozzle 30 into the circulation duct 28. The Onerschnitt the nozzle opening is adjustable relative to a lying in the course of the rich-gas channel 29 Venturi channel 33rd

The strong gas exiting the strong gas nozzles 30 under pressure exerts an injector effect and sucks exhaust gas through the circulation channels 28 from the associated heating flues of the adjacent heating wall standing on flue gas in order to form an elongated flame in the heating flues.

The upper part of the regenerator walls 21 and the entire upper structure of the furnace consist of silica bricks 6. The lower part of the regenerator walls is made of clay-bound bricks 9 . As can be seen from FIG. 3 , the wall-bound masonry of the furnace substructure can extend up to a mean height 32, preferably up to a height 36 of the regenerator from the furnace support plate 20. It can also be sufficient to produce only the masonry in the area of the base channels from clay-bound building material.

When the furnace battery is heated, the clay-bound masonry 9 expands only slightly from the central vertical plane 39 to both furnace battery sides 40, 41. This break is at the sur- face of the concrete slab practically no more than the expansion of the clay-bonded masonry bearing concrete slab 20. The slab expands mm at the conditions prevailing in this one area temperatures about 6.4, while resting on the concrete slab tonerebundene masonry itself stretches about 5.5 mm. In Be-ZD of Sohlkanaldecke 42 reaching the elongation about 10 mm to j Eder battery side 40, 41. The down to the Sohlkanaldecke 42 guided down Silikamauerwerk 6, however, extends to the clay-bound masonry about 63 mm. The masonry 6 must therefore be erected in the cold state in such a way that the lower opening of the vertical high-gas duct 19 runs in the course of the venturi duct 33 in the clay-bound masonry 9 of the duct of the concrete slab 20 and the gas pipe 29 opening into it when the heating of the furnace battery ends is.

If the clay-bound masonry of the furnace support plate 20 is up to a quarter of the height of the regenerator, about 900 mm high up to level 36 in the temperature range of about 550 ° C, while the masonry above consists of silica bricks, the silica masonry expands in this Level 68.5 mm on each side of the furnace battery, the clay-bound masonry at this connection point, however, only 17 mm.

If the clay-bonded masonry is raised up to a temperature range of 650 ° C, approximately at height 32 of the regenerator, the silica masonry in this level expands to 64 mm on each side of the furnace battery, whereas the clay-bonded masonry only extends 22 mm.

The stones forming the ceiling 42 of the bottom channel 7 consist of clay-bound plates supported in the regenerator walls 21. The bottom of the sole channel is covered with thin clay-bound plates 46. The usual lateral clay-bound stones of the sole channel 7 are no longer necessary, since the sides of the stone-bound stones forming the walls of the sole channel simultaneously form the side surfaces of the sole channel 7 . The bottom channels 7 therefore have a greater width with a height reduced by approximately 25 mm, with the same cross section, whereby the regenerator height and the total height of the furnace battery are reduced.

The furnace support plate. 20 is provided at its ends on both sides of the furnace battery with supports 47 enclosing the clay-bound masonry. The waste subsidies 47 forming the top of the upper end plane of the clay-bound masonry and form the support surface of the armature stator 48. hold the upper ends of the anchor stands the furnace masonry by lying in the furnace ceiling tie rods 49 and their lower ends by the oven support plate 20 or the waste support 47 anchored anchor supports 50 adjustable together. The anchor supports 50 are connected to the abutment 47 at 51 by screws. A screw 53 supported on the anchor supports 50 acts adjustably against the anchor stand by means of a spring 52. The supports 47 are made of concrete with steel inserts 67. In the course of the bottom channels 7 , openings 54 are arranged in the support 47, into which the changeover devices 18 with their changeover devices 55, 56, 57 for the combustion agent and lean gas open. These switching devices are located on the furnace battery sides 40, 41 between the upper part of the support 47 and the surface of the furnace support plate 20.

Anchoring the anchor stands on the support above the changeover devices results in a shorter construction of the changeover devices 18 and better accessibility for the purpose of sealing at the connection point with the feed channels to the regenerator base channel as well as better accessibility to the anchoring at the lower ends of the anchor stands. The shorter design of the changeover devices also results in a larger free space for attaching the lean gas line.

Another advantage of the arrangement of the anchor stands in the upper part of the regenerators, regardless of the clay-bound masonry lower part, is a reduction in the deflection of the anchor stands 48 due to the different expansion of the furnace in the different height areas. In the case of silica masonry with an area extending from the ceiling of the furnace chamber up to a temperature range of 650 ° C. in the middle height of the regenerators in level 32 , the greatest expansion occurs across the furnace battery with 74 mm. If the entire furnace walls to the concrete plate made of silica bricks, so it expands in a temperature range of 550 'C in the plane 36 920 mm above the Regeneratorsohle to about 68.5 mm and in the temperature range from 40011 C to the ceiling of Silikasohlkanals 7 to about 63 , 5 mm. If the floor channel consists of clay-bound stones in the area of the ceiling 42 of the floor channel 7 up to the surface of the furnace support plate 20, the expansion is much lower, namely about 10.30 to 5.30 mm, than if the floor channel consists of silica stones, which stretch in the same range about 63.5 to 40.5 mm. Therefore, the degree of bulge of the anchor posts with clay-bound building material, as indicated by the line 62 , is significantly less than the bulge indicated by the line 62 when using silica building material.

The Venturi channel 33 in the course of the vertical high-pressure gas channels 19 is advantageously arranged in the clay-bound masonry part 9 of the reggenerator walls, while the circulation channels 28 and the nozzles 30 are located in the furnace support plate 20. There are therefore no difficulties in centering the nozzles 30 with the Venturi channel 33 when the furnace battery is heated, since the coefficient of thermal expansion of the concrete furnace support plate 20 is only slightly higher than that of the clay-bound masonry 9. The furnace battery can therefore be built in this way when cold that the Venturi channel 33 is offset from the outlet 64 of the connecting channel 66 of the circulation channel 28 , and after the furnace battery has been heated it is in such a position that the passage of gas through the heavy gas channels 19 is not disturbed. For the exact central position of the lower end 65 of the heavy gas cartridges 19 , it is therefore irrelevant whether the refractory Manerwerk consists of clay-bound or silica stones.

In order to ensure the continuous connection of the venturi channel 33 in the clay-bound part 9 in the area of the base channel with the heavy gas channel 19 located in the silica masonry, when using silica building material, especially above the base channel ceiling 42, the lower end of the silica part of the heavy gas channel 19 is conically widened downwards, as indicated at 65 (Fig. 4).

The stones of the clay-bound masonry 9 are provided with interlocking tongues 68 and grooves 69 (Fig. 5). In this way a movement of the clay-bound stones in the direction transverse to the furnace battery during the expansion of the silica masonry is avoided. Furthermore, the clay-bound stones are provided in thin joints with the usual air-drying mortar, which has a greater bond strength at the operating temperatures due to chemical additives. Furthermore, any unevenness in the stone surfaces is evened out by a thin layer 71 of the air-drying cement at the junction of the silica masonry with the clay-bound masonry as well as at the junction of the concrete slab.

Furthermore, a graphitic or a similar lubricant is applied to the surface of the clay-bonded masonry, which quickly solidifies at the heating temperatures of around 320 to 370 ° C in this area, in order to ensure that the silica superstructure 6 glides safely on the clay- bonded substructure 9 without abrasion of the clay-bonded one To achieve masonry and without exerting a destructive pressure against the concrete wall.

A clay-bound wall formed in this way is very strong against mechanical ones Influences and practically gas-tight, and the joints are also mechanically strong, so that the entire clay-bound masonry has a concrete-like uniform structure receives.

The binding of the clay-bound stones can except with tongue and groove can also be achieved by other means to achieve an anchoring of the stones. For example, heat-resistant metals can be inserted into the joints of the stones, to connect them together. Wires, rods or the like can also be used for anchoring The clay-bonded bricks are used to prevent the silica masonry from sliding without tearing to achieve the clay-bound stones.

The clay-bound part of the regenerator walls 21 does not exert any pressure against the supports 47 when the silica masonry 6 expands, since the clay-bound masonry does not expand any more than the concrete furnace support plate 20.

In the event of undesirable expansions occurring under unfavorable operating conditions, the joint between the support 47 and the clay-bound masonry 9 of the regenerator wall 21 can be filled with a flexible material 74.

While the furnace battery is heating up, it is not necessary to to make a heating of the circulation channels, since these in the area of the only slightly stretching clay-bound masonry.

Furthermore, when changing the heating during operation, in particular at lower temperatures, no cracks appear in the clay-bound masonry, as this is not subject to contraction due to the low expansion coefficient. One about due to stronger heating, however, caused minor Stretching has the effect of compressing the soft packing in the joint of the supports 47 or a closure of the joints without a destructive effect on the above of the clay-bonded masonry to exercise arranged silica masonry.

Claims (2)

PATENT CLAIMS: 1. Regenerative coke oven battery, in which the substructure in the area of the bottom channels and the lower part of the regenerators up to a temperature range of about 650 ° C are made of clay-bound building material and the overlying part of the regenerators and the superstructure are made of silica building material, characterized in that the substructure (9) consisting of clay-bound building material lies within supports (47) which are made of the same material as the furnace support plate (20) and are connected to it by reinforcements (67) , the supports (47) also via adjustable anchor posts (Form 50 # abutments for the vertical anchor stands (485. 2. Regenerative coke oven battery according to claim 1, characterized in that the clay-bound stones (9) of the substructure are provided with interlocking tongues and grooves and the stones at the junction between the clay-bound and silica masonry (6) with smooth surfaces with the interposition of a #Terschrift des Silica masonry on the clay-bound masonry enabling lubricants (72) lie on top of one another. In, considered publications: Technische Mitteilungen, May 1955, pp. 173 to 176.