DE1196221B - Shaft furnace for the scaling-free heating of long metallic workpieces and processes for its operation - Google Patents

Description

Shaft furnace for scaling-free heating of long metallic workpieces and method for its operation. The invention relates to shaft furnaces for non-ignition Heating of long metallic workpieces such as steel shafts, steel domes or the like.

So far it has been used for the heating of steel shafts, steel mandrels, Blocks and the like that are long, shaft furnaces with direct heating. the Workpieces are placed in the furnace, the work space being lined with a brick Lid is closed, or they are hung up with tongs. At this However, the type of heating occurs as a result of exposure to higher temperatures and a Long heating time to a strong scaling of the workpieces, both by the action of a certain amount of oxygen as well as by the action of the carbon dioxide contained in the products of combustion.

The scale layer amounts to 3 to 4 percent by weight of the heated parts with normal heating or 2 to 3 % with strong reduction combustion. This results in great losses of the heated material and great losses of fuel, since the scale that has fallen to the bottom of the shaft furnace has to be removed either by melting it out or in some other way.

The scale-free heating or annealing of long pieces of steel is in Muffles of kilns of the chamber type are already known.

A disadvantage of the previous heating process is the heavy burn-off. The surface of the material is attacked as a result of the action of scale and gets rough. Another disadvantage is that when removing scale from the bottom of the shaft furnace the operation has to be interrupted and that this increases the fuel consumption; Finally, the chemical action of the slag increases the service life of the furnace lining degraded.

The disadvantages of heating a long workpiece in muffle furnaces consist in the fact that this is tedious and associated with a higher heat consumption and that the lining costs are also higher. It is true that one achieves in these ovens a smaller burn, but you don't have the option of heavy and strong burns To process steel workpieces and to heat them evenly.

The above-mentioned disadvantages are intended according to the invention be eliminated that the work space to accommodate the long metallic workpieces of a row of concentrically stacked heating rings with a parabolic inner profile is formed. The heating burner and exhaust ducts lead tangentially into the parabolic focal points. Ribbed rings with radial channels are provided between the heating rings Channels are connected to a recuperator serving to heat the protective gas.

The operation of the shaft furnace SUC erfindunasgt C Cremäß such that the air flowing in through the channels in the t3 ribs rings, for generating a protective layer which serves to clamp the workpieces protection C aas under a higher pressure than the tangentially entering through the burners in the heating rings combustion means in the Work space is introduced. Only in the contact areas between the circulating combustion products and the protective layer does a part of the protective gas react with the excess oxygen contained in the combustion products. The combustion products are pushed outwards in the heating rings due to the effect of centrifugal force and due to their higher specific weight in comparison with the protective gas.

3 By the invention the advantage is obtained that, in the inventive design the shaft furnace C, long objects can be heated free of scale, with weight losses alloy steel materials can be kept small.

The surface of the heated objects remains smooth and intact. As a result of the heating by the highly heated parabolic surface of the heating ring the heating takes place in an intense and even manner. The lifespan the brick lining increases, because the fact that no scale is formed arises also no slag, which increases the heat resistance and lifespan of the lining belittles. Since the insert is heated evenly from all sides, that is Melting off of the scale is not necessary, which increases the specific heat consumption decreased.

A practical embodiment of the shaft furnace according to the invention is shown in FIGS. 1 to 5 shown. It shows F i g. 1 shows a longitudinal section through the shaft furnace, in which the working space with the heating rings is shown, FIG . 2 shows a section of the shaft furnace with the division of the tangential openings for the supply of the hot combustion products into the heating rings, FIG . 3 shows a cross section of the shaft furnace, from which the arrangement of the heating burners can be seen, FIG . 4 shows a cross section of the shaft furnace, from which the channels in the rib rings for the distribution of the protective gas can be seen and FIG. 5 shows a diagram of the division of a larger number of shaft furnaces.

The shaft furnace forms an independent heating unit with a ceramic recuperator 8 and a metal recuperator 9. The working space 1 is formed by a series of heating rings 2 with parabolic curved surfaces into which the hot combustion products are introduced from the tangentially arranged burners 3 . The hot combustion products give off their heat to the parabolic surface of the heating rings 2, which irradiate the workpiece 14 to be heated. The protective gas flowing out of the radial channels 6 of the rib rings 5 has a composition such that heating without scale is guaranteed. In the working space 1 , the protective gas is introduced with a certain excess pressure, which is used to form the protective layer on the surface of the heated workpieces 14, while the glowing combustion products are tangentially supplied with a certain excess of air to the apex of the parabolic curvature of the heating ring 2, so that the hot combustion products have an oxidizing composition. As a result of the centrifugal force of the flowing combustion products and the effect of pressure from the protective gas, a protective gas layer is created at a certain distance from the heated object 14. The combustion products are discharged through the exhaust ducts 4, which are carried out in each heating ring 2 in front of the tangentially arranged burners 3 , into the vertical exhaust ducts 10 and from here into the ceramic recuperator 8 . The air nozzles 11 are arranged in front of the recuperator 8. through which combustion air is supplied for the combustion of the remaining part of the combustible protective gas parts. The combustion products continue to flow through the metal recuperator 9 into the main exhaust duct 15. The protective gas is fed through the ceramic recuperator 8 , preheated to a high temperature and continues to flow through the ducts 7 into the radial ducts 6 and into the working space 1.

The combustion air is heated in the metal recuperator 9 and is fed to the shaft furnace (not shown) and to the individual burners 3 . In order to be able to regulate the draft conditions in the working space 1 , a slide 12 is provided in front of the ceramic recuperator. In the upper part of the working space, a water-cooled sealing ring 13 is arranged, which cools the upper part of the suspended workpieces. The shaft furnace is arranged in the concrete pit 16 ; the free space around the stove is provided with a grate-17.

In Fig. 5 shows the division of independent shaft furnaces for larger capacities. The grouping is carried out in such a way that all the shaft ovens can be connected to a discharge duct 15 on one side.

Claims (2)

1. A shaft furnace for scale-free heating of long metal workpieces, d a d u rch in that the working space (1) is formed by a series of concentric superposed heating rings (2) with parabolic inner profile, wherein heating burners (3) and exhaust ducts (4) Open tangentially into the parabolic focal points, and rib rings (5) with radial channels (6) are provided between the heating rings, which are connected via channels (7) to a recuperator (8) used to heat the protective gas. 2. A method for operating the shaft furnace according to claim 1, characterized in that the incoming through the channels in the ribbed rings, serving to generate a protective layer around the workpieces protective gas under a higher pressure than the incineration agent flowing tangentially through the burner in the heating rings in the Working space is introduced and that only at the contact surfaces between the circulating combustion products and the protective gas layer, a part of the protective gas reacts with the satire excess contained in the combustion products, the combustion products being due to the effect of centrifugal force and due to their higher specificity in comparison with the protective gas Weight in the heating rings to be pressed outwards. Oezocene publications to be considered: German Patent Specifications No. 423 504, 377 738; FranzZ3s-Ische patent specification No. 1237 690.