EP0033874B2 - Cooler for the dry cooling of coke - Google Patents

Abstract

A cooling device for coke dry cooling, has a housing composed of upper and lower parts connected with one another by a slide joint, and a ring-shaped insert located inside the upper part of the housing and constituted of a metallic heat-resistant material, coated by a wear-resistant and heat-resistant coating layer. The insert is conical and mounted by its upper end portion on the upper part of the housing.

Description

The invention relates to a cooler for coke dry cooling, which has an annular installation in its upper part in the area of the exhaust line for the gaseous cooling medium.

For dry coke cooling, cooler designs have been known for a long time, in which the gaseous cooling medium is drawn off from the upper part of the cooler via an annular channel arranged in the masonry of the cooler lining. The disadvantages of this embodiment can be seen above all in the fact that a large number of complicated stone shapes are required for the lining of the ring channel and that overall an extraordinarily large amount of refractory lining material is required for such an embodiment. In addition, due to the different thermal expansion between the inner and the outer jacket of the cooler when it was cold driven, damage to the refractory lining almost always occurred, which in this embodiment can be repaired hardly or only with great difficulty and with a considerable expenditure of time and material .

It has therefore already been proposed to provide the cooler with an annular installation which projects from above into the interior of the cooler into the area of the exhaust line for the gaseous cooling medium. Such an embodiment is shown for example in Fig. 1 of DE-OS 27 00 783. The hot coke filled into the cooler from above forms an embankment when it emerges from the annular installation, through which a closed annular space is created between the inside of the cooler and the outside of the annular installation. Since the outlet line for the gaseous cooling medium is also located in this area, the hot gases escaping from the coke to be cooled can reach the outlet line via the annular space. Although a certain simplification and improvement over the construction described above is achieved with this embodiment, it is also not yet completely free from disadvantages.

In this embodiment, the ring-shaped installation together with the rest of the radiator lining is made entirely of fireproof masonry. This means that the disadvantages described above also occur here, albeit in a weakened form.

From US-A 3 795 987 a one-piece device for cooling or preheating coarse-grained bulk material is known, which consists of a steel jacket, which is either provided with a lining on its inside, or in which the outside is equipped with a cooling system. A gas collecting space is provided in the upper part of the device, which is separated from the actual cooling chamber by a wall provided with gas passage openings. The bulk material is fed into the device by means of a sleeve-like cylindrical piece of pipe which connects the top surface of the device to the wall provided with gas passage openings.

US Pat. No. 4,141,795 shows a device for dry coke cooling in which, based on the embodiment described above, the gaseous cooling medium is drawn off via an annular channel embedded in the cooler wall lining. However, the patent specification does not provide any details as to how the radiator wall lining is to be designed.

DE-C-492 943 describes a coke cooling system which, with a one-piece overall construction, includes a cooling chamber which is formed by cooling pipes. Here too, as with US Pat. No. 3,795,987, the hot coke is charged via an obviously tubular connection piece into the inner chamber formed from cooling pipes, which is arranged within a one-piece, outer enclosure.

The journal Glückauf 114 (1978), pages 615-616, reports on a coke dry cooling system operated by the Nippon Steel Corporation at the Tobata coking plant. From the flow diagram of this system shown there, however, no concrete indications for the creation of the device according to the invention can be derived.

• 1. Leichtere und unkompliziertere Konstruktion mit einem geringeren Bedarf an feuerfestem Material.
• 2. Herabsetzung der durch Wärmedehnung bedingten Reparaturanfälligkeit, insbesondere beim Heiß- und Kaltfahren des Kühlers.
• 3. Gute Regelbarkeit des aus dem zu kühlenden Koks austretenden Gasstromes und damit günstige Beeinflussung der Strömungsverhältnisse und der Betriebsbedingungen im Kühler allgemein.

The invention is based on the object of constructively improving the above-described embodiments of a cooler for coke dry cooling, the following points in particular being taken into account:

• 1. Lighter and less complicated construction with less need for fireproof material.
• 2. Reduction of the susceptibility to repairs due to thermal expansion, especially when the cooler is hot and cold.
• 3. Good controllability of the gas stream emerging from the coke to be cooled and thus a favorable influence on the flow conditions and the operating conditions in the cooler in general.

• a) der Kühler umfaßt einen Oberteil und einen Unterteil wobei zwischen dem Oberteil und dem Unterteil eine Gleitfuge vorgesehen ist,
• b) der ringförmige Einbau ist aus einem hitzebeständigen metallischen Werkstoff gefertigt und an seiner Innenseite mit einer geeigneten Verschleißund Hitzeschutzschicht versehen,
• c) der ringförmige Einbau ist nur an seinem oberen Ende über eine geeignete Befestigungsvorrichtung mit dem Oberteil des Kühlers verbunden,
• d) der ringförmige Einbau weist eine konische Form auf.

The cooler of the type mentioned at the outset, which is used to solve this problem, is characterized according to the invention by the following design features:

• a) the cooler comprises an upper part and a lower part, a sliding joint being provided between the upper part and the lower part,
• b) the ring-shaped installation is made of a heat-resistant metallic material and is provided on the inside with a suitable wear and heat protection layer,
• c) the ring-shaped installation is only at its upper end via a suitable fastening device connected to the top of the radiator,
• d) the annular installation has a conical shape.

It has proven to be advantageous that the annular installation has a conical shape instead of the previously customary cylindrical shape, because this creates a relatively large annular space between the inside of the cooler and the outside of the annular installation, which already has a relatively good shape due to its conical shape Distribution of the gases deviating from the coke over the entire circumference.

If necessary, suitable internals can also be provided in the annulus to equalize and / or throttle the gas flow. This can be done, for example, in a particularly simple form in that a support ring is fastened to the outside of the ring-shaped installation, while the opposite refractory radiator lining has a corresponding recess, so that the installations can rest loosely on the support ring and the opposite recess. These internals can also consist of a heat-resistant metallic material. But it can also be fireproof shaped stones such. B. so-called slide stones come to use.

Finally, it has proven to be advantageous if the connecting piece for the exhaust line for the gaseous cooling medium has a round cross section.

Further details of the cooler according to the invention will be explained below with reference to the figure. This shows as a longitudinal section only that part of the cooler which is necessary for explaining the design features essential to the invention. In contrast, the upper end of the cooler with the feed device for the coke to be cooled and the lower end of the cooler with the discharge device for the cooled coke and the gas inlet nozzle are not shown. However, it is assumed that it is a cooler in which, in a manner known per se, the coke to be cooled, which is fed in from above, is treated with a gaseous cooling medium rising in countercurrent from the bottom up. Of course, there are different design options for the parts of the cooler that are not shown in the figure. However, the invention is not tied to any specific embodiment.

In the figure, the ring-shaped installation 1 has a conical shape. The cone jacket 2 consists of a heat-resistant metallic material, for. B. heat-resistant steel. The wear and heat protection layer 3 is attached to the inside of the cone jacket 2. This can consist of fireproof masonry or fireproof spray or ramming compound. Finally, it is also possible to protect this protective layer by so-called. Apply flame spray. In addition, it does not have to be a completely homogeneous protective layer; B. also consist of two superimposed layers with different material properties. For example, the top layer can be distinguished by a particularly high wear resistance, while the layer underneath has a particularly good insulation capacity. In this case, the ring-shaped installation 1 is suspended via the ring-shaped bracket 4, which is fastened to the outer radiator jacket 6 by the anchors 5. Between the upper edge of the conical jacket 2 or the bracket 4 and the radiator jacket 6 there is still the gas-tight seal 16, which also provides a certain amount of heat insulation to the radiator jacket 6.

In contrast to known constructions, the cooler in the present case is not provided with a continuous outer cooler jacket 6, but consists of an upper part 7 and a lower part 8, which are connected to one another via the sliding joint 9. The inner diameter of the upper part 7 is adapted to the outer diameter of the lower part 8, so that it can grow freely into the upper part 7 when the cooler is heated, without the latter having to change its position to the appropriate extent. Correspondingly, the conditions are also the same when cooling, when the lower part 8 is subjected to shrinkage.

Since the ring-shaped installation 1 is only suspended from the bracket 4 in the manner described above, its position is only influenced by the vertical thermal expansion which occurs in the area of the bracket 4 and on which the thermal expansion of the lower part 8 no longer has any influence Has.

The support ring 10 is attached to the outside of the cone jacket 2, while the opposite radiator lining 11 has a recess 12 at the height of the support ring 10. As a result, it is possible in a simple manner to install the internals 13 required for the equalization and / or throttling of the gas flow. As already stated, these can consist, for example, of so-called slide stones or similar refractory shaped stones which are simply placed loosely on the support ring 10 and the recess 12. Of course, the internals 13 are evenly distributed over the entire cross section of the annular space between the cone jacket 2 and the radiator lining 11.

The mode of operation of the cooler shown in the figure has already been briefly explained above. This means that the coke to be cooled is also poured into the cooler from above. When the coke runs out of the ring-shaped installation 1, it forms an embankment which extends from the cooler lining 11 to the lower edge of the conical jacket 2. This creates Above the slope, not shown in the figure, the closed annular space 14, in which the hot gases rising from the coke can collect, the internals 13 ensuring a uniform distribution or throttling of the gas flow. In the annular space 14, the connecting piece 15 opens for the exhaust line, no longer shown, through which the hot gases are drawn out of the annular space 14 and fed to a suitable heat recovery device. For structural reasons, the connection stub 15 preferably has a round cross section.

The shaded areas in the figure each represent the radiator lining. It has been shown that using the construction according to the invention can save more than 50% of the previously required requirement for refractory material. The arrangement of the sliding joint 9 according to the invention greatly reduces the susceptibility to repairs of the radiator due to stress or expansion cracks in the refractory material of the radiator lining. If, contrary to expectations, damage should occur, it can be repaired relatively easily and at a relatively low cost because of the simplicity of the proposed construction and its good accessibility and due to the fact that only a small number of stone molds are required for the radiator lining.

Claims (4)

1. Cooler for the dry cooling of coke, which possesses, in its upper part in the region of the offtake main for the gaseous coolant, an annular insert, characterized by the following constructional features :

a) the cooler comprises an upper part (7) and a lower part (8), a sliding joint (9) being provided between the upper part (7) and the lower part (8),

b) the annular insert (1) is manufactured from a heat-resistant metallic material (2) and is provided, on its inner surface, with a suitable protective layer (3), protecting against wear and heat,

c) the annular insert (1) is attached, at its upper end only, to the upper part (7) of the cooler via a suitable securing device, and

d) the annular insert (1) is of conical shape.

2. Cooler according to Claim 1, characterized in that internal fittings (13) for blending and/or throttling the gas flow are located in the annular space (14) between the inner surface of the cooler and the outer surface of the annular insert (1).

3. Cooler according to Claims 1 and 2, characterized in that the internal fittings (13) consist of a heat-resistant metallic material and/or moulded refractory bricks and are supported, in a loose manner, on a support ring (10) at the annular insert (1) and on a recess (12) in the cooler lining (11

4. Cooler according to Claims 1 to 3, characterized in that the connecting pipe-section (15), on the offtake main for the gaseous coolant, has a circular cross-section.

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