EP0116272A2 - Manufacturing process of silicon and iron free blast material for surface treatment - Google Patents

Abstract

1. Manufacturing process for a silicosis and iron-free blast material for surface treatment, in particular of Austenitic steels, with a maximum grain size of 0.5 mm, made of crushed smelter slag granulate from hard coal combustion, characterized by crushing of the smelter slag granulate to the desired size before the raw material (with a maximum total iron content of approximately 7 % by weight, primarily occuring as iron silicate and iron aluminate) undergoes magnetic separation, resulting in a maximum metallic iron content of 0.1 % by weight.

Description

The invention relates to a process for the production of a silica-free and iron-free blasting agent for surface treatment, in particular of austenitic steels, with a grain size of at most 0.5 mm from melt chamber slag granules derived from hard coal furnaces.

At the moment, only abrasives are used for the surface treatment, in particular of austenitic steels, such as electro-corundum, zircon sand and glass beads that are almost iron-free. The iron oxide content is limited to a maximum of 0.1% by weight.

From "Stahl und Eisen" 75 (1955), pages 1115 to 1117, it is already known to grind abrasives from refractory slag for certain purposes to a grain size below 0.5 mm. The crushing process already brings about the final state of the abrasive in terms of composition and properties.

The object of the invention is to enable the production of a further silicon-free and iron-free abrasive which is also particularly suitable for the surface treatment of austenitic steels and is not very expensive. This is said to be the starting material in coal-fired furnaces resulting melt chamber slag granules are used.

The stated object is achieved by a method which has the features of patent claim 1. Thereafter, the melting chamber slag granules are comminuted to the desired grain size before the resulting raw material with a total iron content of at most about 7 wt becomes.

Magnetic separation, in which a thin layer of raw material is preferably passed over magnetic drums, can be carried out in one or more stages depending on the layer thickness and the grain size distribution present; in many cases, a single-stage magnetic separation is sufficient to achieve or fall below the required metallic iron content of at most 0.1% by weight.

The surprising result achieved with the proposed method is that the above-mentioned maximum proportion of metallic iron can be maintained with the specified, less complex measures, although the total iron content of the raw material present after comminution is several times the factor 10 greater than the maximum proportion to be observed.

In addition, corrosion tests with irradiated austenitic steels have shown that treatment with the iron-free abrasive produced in this way does not lead to the formation of extraneous rust. The blasting medium produced according to the teaching of the invention is therefore suitable for replacing the known blasting medium mentioned at the outset.

The surfaces achieved by means of the abrasive are kung (surface roughness of the irradiated surface) can be adjusted by changing the grain size distribution of the blasting agent; a lower surface roughness can be achieved in particular by reducing the maximum permissible grain size.

The process can in particular be carried out in such a way that the desired grain fractions are sieved off only after magnetic separation; However, it is also possible to sieve the raw material before carrying out the magnetic separation and to separate the resulting grain fractions from one another using suitable magnetic separators. Grain screening can take place, in particular, in the fractions that comply with the regulation according to _D IN 8201 for electro-corundum.

The process can in particular also be carried out in such a way that the melt chamber slag granules are comminuted into a raw material with a grain size of at most 0.25 mm before magnetic separation (claim 2); The melt chamber slag granulate is preferably comminuted as a raw material to a grain size which is predominantly in the range between 0.06 and 0.25 mm (claim 3).

It is particularly advantageous to use raw material, the total iron content of which before the magnetic separation is no higher than about 6, preferably 5.5,% by weight (claim 4).

An expedient development of the method according to the invention is that the layer of raw material which is subjected to magnetic separation has a thickness of at most five times, preferably two to three times, the maximum grain size (claim 5).

Generally speaking, the layer in question should be set as thin as possible in order to be able to carry out the deposition of metallic iron as effectively as possible and, if possible, already in a single deposition stage. The layer thickness can be adjusted in particular by suitable coordination between the amount of comminuted raw material fed in and the speed of the magnetic separator (s).

The abrasive produced from hard coal furnaces according to the teaching of the invention using melt chamber slag granules has the following typical chemical composition; the individual components are each given in% by weight:

The particle size distribution of the abrasive is as follows:

The abrasive therefore consists of approximately 70% grains in the range between 0.5 mm and 0.1 mm.

Although an abrasive of the listed composition has a significantly larger total iron content than, for example, zircon sand used for comparison (total iron content only about 0.2% by weight), its use for blasting stainless steels on these does not lead to extraneous rust formation if the melt chamber slag granulate serving as the starting material , which has been converted into a sufficiently comminuted raw material, the metallic iron is essentially removed beforehand by magnetic separation.

The manufacturing method according to the invention described at the outset can in particular be further developed in that the raw material is additionally subjected to a drying process at a suitable time, in particular also simultaneously with or after the magnetic deposition.

The blasting agent produced using the melting chamber slag granulate is also silicon-free, since it has an SiO ₂ or quartz content of about 0.4 to 0.5%. points. A content of free, crystalline silica = quartz is allowed up to 2%.

Claims (5)

1. A process for the production of a silica-free and iron-free abrasive for surface treatment, in particular of austenitic steels, with a grain size of at most 0.5 mm from granular furnace slag granules, characterized in that the granular slag granulate is comminuted to the desired grain size. before the raw material with a total iron content of at most about 7% by weight - in the present case predominantly in the form of iron silicate and iron aluminate - is adjusted to a content of metallic iron of at most 0.1% by weight by magnetic separation. 2. The method according to claim 1, characterized in that the melting chamber slag granules are crushed before the magnetic separation into a raw material with a grain size of at most 0.25 mm. 3. The method according to any one of claims 1 or 2, characterized in that the melting chamber slag granules before the magnetic separation is comminuted as a raw material to a grain size which is predominantly in the range between 0.06 to 0.25 mm. 4. The method according to any one of claims 1 to 3, characterized in that the total iron content of the raw material before the magnetic deposition is not higher than about 6, preferably 5.5 wt .-%. 5. The method according to any one of claims 1 to 4, characterized in that the layer of raw material subjected to magnetic deposition has a thickness at most in the order of five times, preferably two to three times, the maximum grain size.