LU88168A1 - PROCESS FOR REMOVAL OF GALVANIZED SCRAP ZINC - Google Patents

Description

Process for removing zinc from galvanized scrap.

The present invention relates to a process for removing zinc from galvanized scrap.

Galvanized products are currently experiencing increasing use in various fields, in particular because of their good resistance to atmospheric corrosion and their aesthetic appearance. These are in particular thin sheets, used in automobile bodywork and for the dressing of household appliances, and various profiles used in mechanical construction and in metal construction.

This increased use results in the production of an increasing quantity of galvanized scrap, both so-called new scrap and so-called old scrap. New scrap is mainly scrap directly from the manufacturing process; they are generally of good quality, with low contents of residual elements. Old scrap comes mainly from the collection of used vehicles and household appliances; their quality is often poor.

All types of scrap are concerned by the invention, such as crushed or sheared scrap or even so-called "shredder" scrap. These scrap metals can include all types of zinc coated products, namely dip galvanized products, electrogalvanized products as well as so-called "galvannealed" products, that is to say dip galvanized and annealed.

The recycling of galvanized scrap in steelmaking equipment, in particular in oxygen converters and electric ovens, comes up against various drawbacks. It gives rise to the emission of large quantities of white smoke; it also causes zinc pollution of steelworks dust and liquid steel.

We know, in particular from patent application BE-A-09000889, a process for the selective separation of steelworks dust as a function of their zinc content. This process is based on current practice, which consists of melting galvanized scrap and trying to recover the zinc entrained in the fumes. This technique presents only a limited recovery yield, and it does not eliminate the risks of pollution of dust and steel.

The subject of the present invention is a process for removing zinc from galvanized scrap which makes it possible, by simple means, to separate and recover the zinc separately from these scrap before they are placed in the steel making machine.

According to the present invention, a process for removing zinc from galvanized scrap is characterized in that said scrap is heated to a temperature equal to or higher than the vaporization temperature of zinc, in that it is kept at this temperature. temperature for a predetermined period, in that the zinc vapors are captured and in that the zinc is collected by condensation of said vapors.

It has been found to be advantageous to essentially heat the surface layer of said galvanized scrap.

This surface heating can be achieved by any means known per se. However, it is preferable to carry out this surface heating of the scrap by high frequency electrical induction.

In particular, it is advantageous to heat the galvanized scrap in two stages. The first step consists of preheating to a temperature at least equal to the Curie point of the steel, ie approximately 770 ° C; for this first step, a frequency which does not exceed about 10 kHz is used. The second stage constitutes the actual heating to the temperature required to vaporize the zinc; it uses a frequency greater than 100 kHz, and preferably between 200 kHz and 300 kHz. The temperature required for vaporization of the zinc should be above about 910 ° C, which is the point of vaporization of pure zinc, and is preferably between 1000 ° C and 1200 ° C.

According to an additional characteristic of the process of the invention, the galvanized scrap is heated under a neutral atmosphere, such as a nitrogen atmosphere, or slightly reducing, such as a nitrogen atmosphere containing a small amount of gas reducer. For example, this reducing gas can result from the combustion of residual oils or greases present on the surface of galvanized scrap.

The duration of the heating depends on the one hand on the temperature to be reached and on the other hand on the induction frequency used.

The duration of the zinc vaporization temperature is adjusted according to the nature of the coating, its thickness and the target temperature.

In principle, the holding time can be very short, since the zinc begins to vaporize as soon as the temperature reaches the level indicated above. However, it appears that a minimum duration, generally around 20 s, is necessary to remove more than 90% of the zinc coating from the scrap.

The zinc vapors from the scrap are cooled and condense in the form of a fine zinc powder, which is collected for later use.

When the zinc has been eliminated, the scrap can be recycled. They can for example be immediately loaded into a converter or an electric oven to be remelted there; we can thus take advantage of the heating they underwent for the elimination of zinc. With this in mind, they could also be dezinced directly in the steel plant, by adapting it to the conditions of the present process. They can also be cooled for later recycling, possibly after transport to another installation.

The process of the invention is, however, independent of any operation for recycling scrap iron in a steelworks; it can therefore be used in any appropriate installation, possibly located outside the steel plants. Furthermore, the scrap is normally heated in the absence of air and without contact with burnt gases or fumes. The zinc collected therefore contains practically no impurities. Depending on the needs of the subsequent recycling of zinc, a variant of the process includes the oxidation of zinc fumes and the formation of zinc oxide dust.

Claims (11)

1. A method of removing zinc from galvanized scrap, characterized in that said scrap is heated to a temperature equal to or greater than the vaporization temperature of zinc, in that it is kept at this temperature for a predetermined period , in that the zinc vapors are captured and in that the zinc is collected by condensation of said vapors. 2. Method according to claim 1, characterized in that the surface layer of said scrap is heated. 3. Method according to either of Claims 1 and 2, characterized in that said heating is carried out in two stages, in that the first stage consists in preheating the scrap to a temperature at least equal to Curie point of the steel and in that the second stage constitutes heating to the temperature required for the vaporization of the zinc. 4. Method according to either of claims 1 to 3, characterized in that said heating is carried out by high frequency electrical induction. 5. Method according to either of claims 3 and 4, characterized in that one uses for said first step an induction frequency which does not exceed about 10 kHz and in that one uses for said second step an induction frequency greater than 100 kHz. 6. Method according to claim 5, characterized in that one uses for said second step an induction frequency between 200 kHz and 300 kHz. 7. Method according to either of claims 1 to 6, characterized in that said scrap is heated to a temperature between 1000 * C and 1200 # C. 8. Method according to either of claims 1 to 7, characterized in that Von performs the heating of galvanized scrap under a neutral atmosphere, respectively a slightly reducing atmosphere. 9. Method according to claim 8, characterized in that said neutral atmosphere is a nitrogen atmosphere. 10. The method of claim 8, characterized in that said slightly reducing atmosphere consists of a neutral gas containing a small amount of reducing gas. 11. Method according to either of claims 1 to 10, characterized in that one causes the oxidation of said zinc vapors and in that one recovers the zinc in the form of a dust of 'zinc oxide.