DE1212568B - Gout platform for scaffolding blast furnaces - Google Patents

Description

Gout platform for scaffolding blast furnaces The invention relates to a furnace platform for scaffoldless blast furnaces, where the to accommodate the from the connection moments of the Könsolen resulting horizontal forces above and below the brackets Rings are movably connected to the furnace shell in such a way that the Rings acting forces are introduced tangentially into the furnace shell.

In the known constructions of furnace platforms for scaffold-free blast furnaces, all the forces resulting from the load of the overhead construction comprising the hopper, the bell levers, the overhead crane and the necessary operating platforms, as well as all forces from the load of the furnace platform and the shaft platforms are transferred via a large number of consoles , which are attached directly to the furnace shell, introduced into the furnace shell. As a result of the large size of the overcast construction as well as the gout platform and shaft platforms, the mass of the forces does not act in the plane of the furnace shell, but about 2.5 to 3.5 m outside this plane, which creates considerable connection moments at the Kosol connections. As a result of these connection moments, the relatively thin cylindrical or conical shell of the furnace shell is heavily loaded in the radial direction, which can lead to deformations or cracks in the furnace shell at the connection points of the consoles.

To eliminate this disadvantage, gout stage constructions are already available have been proposed in which rigid rings connected to the furnace shell are arranged are the compressive and tensile forces resulting from the connection moments of the consoles take up. As long as all loads around the furnace occur with double symmetry and the stiffening rings are sized accordingly, the thin cylinder or Conical shell of the furnace shell not claimed. However, such a double symmetry becomes the load is only rarely achieved and then only for the permanent loads. aside from that the radial and tangential forces that occur with this type of gout stage construction their size cannot be determined. But if the cylinder or cone shell in the case of asymmetrical loading, the differential forces that occur are strong as practice shows, where the consoles are used are most heavily loaded with asymmetrical load distribution, again deformations or possibly even cracks in the furnace shell. Also make yourself at the stiffening rings, which are firmly connected to the furnace shell, have considerable thermal stresses noticeable because the heating of the furnace shell is much greater than that of the webs or the external flanges of the ring. As a result, there is a risk that the webs of the stiffening rings penetrate into the furnace shell of the blast furnace and thereby damage it.

The invention aims at the known gout stage constructions to eliminate the disadvantages described above in scaffoldless blast furnaces, and to create a furnace platform in which the radial forces in for the furnace armor harmless, predominantly tangential forces are converted. This goal. will achieved according to the invention in that the closing ring of the gout stage as well the pressure ring, which is designed as torsionally rigid rings, is provided with thrust pieces which engage in pockets provided on the opposite furnace shell. Through this it is achieved that the furnace shell is not subjected to any bending stresses, but only Low torsional stress due to the large diameter of the furnace shell is exposed and, as a result, deformations or cracks in the furnace shell be avoided. In addition, the furnace shell can expand unhindered when heated.

In the drawings is the gout platform on which the invention is based shown schematically in the form of an exemplary embodiment.

F i g. 1 shows the gout platform with the closing ring, the pressure ring and the consoles in a side view, FIG . 2 the gout stage with the closing ring seen from above, F i g. 3 shows an enlarged partial section of the mounting of the locking ring corresponding to point A in FIG. 2, Fig. 4 shows a section along the line BB of FIG. 3, FIG. 5 the pressure ring seen from above, F i g. 6 shows an enlarged partial section of the bearing of the pressure ring corresponding to point C in FIG. 5, 4.

F i g. 7 shows a section along the line -DD in FIG. 6.

The force P, which results from the loading of the upper floor structure, the upper floor and the shaft platforms, acts on the furnace platform 1 at a distance a from the vertical plane of the furnace shell 2 and is passed into the brackets 3 . The brackets 3 are only attached to the vertical part of the furnace shell 2. Only the vertical reaction forces of the force P are transmitted to the furnace shell 2 via this connection. The resulting connection moment of the consoles3 is broken down into a horizontal pair of forces with the forces H and H2. The force H i is directed into the gout platform 1, which is designed as a ring carrier, with a closing ring 5 and the force H2 is directed into the pressure ring 4 attached to the brackets 3.

To avoid 'that the forces from the H., and H2 resulting radial Kräfte'R, to R, and radially act on the furnace shell 2, these radial forces in the manner described below in tangentially acting on the furnace shell 2 forces T: , to T., converted (see Figs. 2 and 5). Since the transfer of the tangentially acting forces T, to T, to the furnace shell 2 does not take place in the same plane as the introduction of the radial forces # R1 to R , into the furnace platform 1 or into the pressure ring 4, this pressure ring 4 is a torsionally rigid ring carrier formed, while the gout platform 1 is provided with a torsionally rigid end ring 5. For the conversion of the radial forces Rf to R 8 into taugential forces TI to T acting on the furnace shell 2, and thus for the storage of the furnace platform 1 and the pressure ring 4, thrust pieces 6 are attached to the closing ring 5 of the furnace platform 1 and to the pressure ring 4, which in on Opposite furnace shell 2 provided pockets 7 engage (see Fig. 3 and 6). Between the thrust pieces 6 of the closure ring 5 of the furnace platform 1 and the pressure ring 4 and the pockets 7 of the furnace shell 2, spaces 8 are provided in the radial direction. Since the charging platform 1 with end ring 5 and the pressure ring 4 under the action usually occurring -unsymmetrischer radial forces -the effort -auszuweichen, which is only possible in the form of a rotational movement about the axis of the furnace, Laying si 'ch the side surfaces 9 of the Push pieces 6 against the side surfaces 10 of the pockets 7.

By attaching the intermediate spaces 8, the initially radially auftretendenBelastungen RI are to R, until T "8 initiated as harmless to the furnace shell 2 tangential T. in these and also is -. ... the thermal expansion of the furnace armor 2 facilitated.

Although the transmission of small radial forces is possible with the new - non-compliance platform construction, these small radial forces are not dangerous for the furnace armor. The conversion of the radial forces into predominantly .-, tangential forces by the new gout stage construction thus prevents z. B. Deformations and cracks occur in the furnace armor.

Claims (2)

Claims: 1. Gicht stage for noiseless blast furnaces, in which the rings arranged above and below the brackets to absorb the liorizontalkruppen resulting from the connection moments of the brackets are movably connected to the furnace armor in such a way that the forces acting on the rings are tangentially in the are conducted furnace armor, characterized denotes Ge, that the end ring (5) of the charging platform (1) and the pressure ring (4), which are formed as torsion-resistant rings are provided with thrust pieces (6) in the opposite furnace shell (2) Engage provided pockets (7) . 2. Gout stage according to - claim 1, characterized in that there are spaces (8) in the radial direction between the thrust pieces (6) of the closing ring (5) and the pressure ring (4) and the pockets (7) of the furnace shell (2) .