AT505289B1 - METHOD FOR HEAT TREATMENT OF A METAL STRIP - Google Patents

Description

2 AT 505 289 B1

The invention relates to a method for heat treatment of a metal strip in front of a metallic coating, wherein the metal strip is first heated in a directly fired furnace part using hot flue gases and then annealed in a furnace section having at least one muffle under a reducing inert gas atmosphere.

For the pretreatment of cold-rolled steel strips for subsequent galvanizing, it is known to first preheat the steel strips in an oxidizing atmosphere in order subsequently to reduce the oxides, which oppose the wettability and adhesiveness, again in a protective gas atmosphere. For this purpose, annealing furnaces are used, which have a directly fired furnace part for heating the steel strips in an oxidizing atmosphere and an adjoining furnace part, which is heated by means of jet pipes and contains a protective gas atmosphere. Thus, when heating the steel strips with the hot flue gases of the directly fired furnace part can build up only a small oxide layer on the strip surface, the fuels used are burned substoichiometric, which post combustion chambers for complete utilization of the fuel energy conditions. Although the flue gases from the directly fired furnace section are also used to preheat the steel strips, the supply of heat from the flue gases, at least in some operating conditions, exceeds the heat requirement for heating the steel strips before entering the directly fired furnace section, thus allowing some of that heat energy to flow through the heat treatment of the steel strips must remain unused.

Since annealing furnaces heated with radiant tubes only have a limited hydrogen content in the reducing protective gas atmosphere for the heat treatment of a metal strip and this limited hydrogen content leads to the desired volume ratio of hydrogen to water vapor to dew points which can not be achieved with such annealing furnaces, heat treatment of metal strips was preferred Metallic coating in a melt or in an electrolytic bath already proposed (AT 500 686 B1) to provide a furnace section with a plurality of juxtaposed muffles, in which the hydrogen content of the inert gas atmosphere can be adjusted accordingly. In a directly fired furnace section upstream of the furnace section with the muffles, the heating of the metal strip can again be carried out in an oxidizing atmosphere of the hot flue gases, resulting in disadvantageous conditions with regard to the utilization of the thermal energy.

The invention is therefore based on the object, a method for heat treatment of a metal strip in front of its metallic coating initially in an oxidizing flue gas atmosphere and then in a reducing inert gas atmosphere so that the available heat energy of the fuel used for the direct firing of the corresponding furnace part completely for the heat treatment the metal strip can be used.

Based on a method of the type described above, the invention solves the task by the fact that the muffle is heated by means of the flue gases from the directly fired furnace section.

By this measure is achieved in a simple manner that the not usable for the heating of the metal strip in directly fired furnace part heat energy of the fuel used for heating the muffle can be used, which is therefore only supply additional heat energy when needed. Since the oxygen content of the flue gases in the region of the furnace part with the muffle on the muffle outside for the treatment of the metal strip under a reducing inert gas atmosphere within the muffle is irrelevant, the post-combustion of the fuel in the furnace part with the muffle under an advantageous supply of combustion air without danger for the bright annealing of the metal strip.

To the growth of an oxide layer on the strip surface during the heating of the 3 AT 505 289 B1

Restricting metal strip in the directly fired furnace section, inert gas from the muffle can be admixed to the flue gases in the directly fired furnace section, which facilitates maintaining a furnace atmosphere with sufficient oxygen concentration to limit the oxidizing effect on the strip surface but sufficient for substoichiometric combustion. The afterburning of the flue gases can be carried out under superstoichiometric conditions while supplying additional combustion air in a flue gas chamber enclosing the muffle.

For carrying out the method, it is possible to start from an annealing furnace with a directly fired furnace part and with an adjoining furnace part, which has at least one muffle enclosed by a smoke gas chamber. It only needs the directly fired furnace part in the downstream side of the flue gases to be connected via at least one flue gas line to the muffle enclosing flue gas chamber to apply the muffle as needed with the still hot flue gases from the directly fired furnace part. The muffle enclosing flue gas chamber can be used as a post-combustion chamber. In addition, it is conventionally possible to supply additional heat energy to the muffle, preferably by means of burners provided in the smoke gas chamber, the flue gases of which then mix with those from the directly fired furnace part. About such burners but could also be blown for cooling only air in the flue gas chamber.

In order for the directly fired furnace section to be supplied with protective gas from the muffle, provision is made for a flow connection between the muffle and the directly fired furnace section in the region of the end face opposite the flue gas line. Such a flow connection requires no special design measures, because yes, the tape guide between the oven parts requires a corresponding connection of the oven parts.

The inventive method for heat treatment of a metal strip before its metallic coating is explained in more detail with reference to the drawing, namely an annealing furnace according to the invention for carrying out the method is shown in a schematic block diagram.

The annealing furnace shown has a furnace part 1 for preheating a metal strip 2 to be treated before its metallic coating in a melt or in an electrolytic bath, a directly fired furnace part 3 and a furnace part 4 with a muffle 5. The arrangement is made such that the metal strip 2 passes through the furnace part 1 from bottom to top and is deflected by a roller box 6 to the directly fired furnace part 3, which is below via another roller box 7 with the muffle 5 in combination, so that the top emerging from the muffle 5 metal strip 2 can be withdrawn via a guide roller 8 through a channel 9. For direct firing of the furnace part 3 10 are provided in this burner, with their hot flue gases in this furnace part 3 downwardly running metal strip 2 is heated in countercurrent.

The directly fired furnace section 3 is connected on the downstream side of the flue gases through a flue gas duct 11 to a muffle 5 enclosing the flue gas chamber 12 through which the muffle 5 is heated, with the aid of the flue gases from the directly fired furnace part 3, as indicated by the dashed flow arrows is indicated. If the heat energy of this branched off into the flue gas chamber 12 flue gases is not sufficient for the respectively necessary heating of the muffle 5, the muffle 5 additional heat energy can be supplied. For this purpose, 12 burners 13 are provided in the flue gas chamber. With the help of these burners 13, a cooling could also be made when only air is blown into the flue gas chamber 12 via the burner nozzles.

The furnace part 1 for the preheating of the metal strip 2 is also heated with the aid of the flue gases from the directly fired furnace part 3. For this purpose, between the furnace parts 1

Claims (6)

4 AT 505 289 B1 and 2 a corresponding connecting line 14 is provided. The branched off to preheat the metal strip 2 from the flue gases of the directly fired furnace part 3 amount of flue gas is adjusted by a control valve 15 in the connecting line 14. The pressure level in the furnace part 1 can be regulated by a throttle valve 16 in the flue gas outlet 17 of the furnace part 1. Similarly, the amount of flue gas flowing through the flue gas chamber 12 of the furnace part 4 and the pressure level in this flue gas chamber 12 are influenced. The control flap in the flue gas duct 11 is designated by 18. The throttle valve in the flue gas outlet 19 has the reference numeral 20. The heat treatment of the metal strip 2 in the muffle 5 is carried out under a protective gas atmosphere. The protective gas is passed in countercurrent to the metal strip 2 through the muffle 5 and passes through the lower roller box 7 in the directly fired furnace part 3, where the inert gas mixes with the flue gases. By the described flue gas guide a direct heating of the metal strip 2 is achieved by the flue gases in the furnace part 3, which are burned to avoid formation of a limited oxide layer on the strip surface in a substoichiometric range, wherein the admixing of protective gas from the muffle 5 the Oxygen concentration can be further reduced. Despite such a stoichiometric combustion of the fuels used, the heat energy of these fuels can be used well, because the flue gas chamber 12 on the one hand and the furnace part 1 for preheating the metal strip 2 on the other hand represent advantageous Nachverbrennungsstrecken. 1. A method for heat treating a metal strip in front of a metallic coating, wherein the metal strip is first heated in a directly fired furnace section using hot flue gases and then annealed in a at least one muffle furnace section under a reducing inert gas atmosphere, characterized in that the muffle (5) is heated with the help of the flue gases from the directly fired furnace section (3). 2. The method according to claim 1, characterized in that in the directly fired furnace part (3) obtained by a substoichiometric combustion flue gases in a muffle (5) enclosing the flue gas chamber (12) are subjected under additional combustion air of a superstoichiometric afterburning. 3. The method according to claim 1 or 2, characterized in that inert gas from the muffle (5) is added to the flue gases in the directly fired furnace part (3). 4. annealing furnace for carrying out the method according to one of claims 1 to 3 with a directly fired furnace part and with a subsequent furnace part, which has at least one of a flue gas chamber enclosed muffle, characterized in that the directly fired furnace part (3) in the region of Outflow side of the flue gases via at least one flue gas line (11) to which the muffle (5) enclosing the flue gas chamber (12) is connected. 5. Annealing furnace according to claim 4, characterized in that the muffle (5) with the directly fired furnace part (3) in the region of the flue gas line (11) opposite end face is in flow communication. 6. Annealing furnace according to one of claims 4 or 5, characterized in that the flue gas chamber (12) burner (13) for additional heating of the muffle (5). 5 AT 505 289 B1 For this purpose 1 sheet of drawings