DE19548645A1 - High grade secondary raw material production for pre-crushed fired brick or roof tiles - Google Patents

Abstract

A process comprises producing high grade secondary raw materials from silicate mineral sorted and comminuted rubble. The prepared rubble is converted to a reactive activated state by tribomechanical and/or tribochemical treatment comprising comminution by impact or friction in a gaseous or liquid phase to form particles with a diameter range (wrt. the maximum value in the frequency distribution) of 0.1 to 30 (preferably 0.6 to 3.0) microns.

Description

The invention relates to a method for producing high-quality secondary raw materials unmixed demolition material from buildings.

Numerous parameters have to be considered when exploring tribomechanical processes [Thiessen, P.-A. Meyer, K .; Heinicke, G .: Basics of Tribochemistry. Treatises of the Germans Academy of Sciences in Berlin, class for chemistry, geology and biology, Akademie-Verlag, Berlin 1967]. An essential part of these tribophysical processes in connection with the Mechanical activation of crystals are the structural changes to tools and Workpiece because it allows conclusions to be drawn about processes such as deformations in the workpiece Crystal surface or in areas close to the surface that result from dislocation formation and movement and reactions result, can be drawn [Thiessen, P.A .: Physikalisch-chem Investigations of tribomechanical processes. In: Thiessen / Meyer / Heinicke, all further details see above]. The increased potential energy content of tribomechanically treated crystals can lead to detected by regression of the deformed crystal areas during temperature treatment on the other hand, it also shows itself through an increased chemical reactivity of the treated substances in relation to their environment [Meyer, K .: Energetically excited, states in tribomechanical processes. In: Thiessen / Meyer / Heinicke, all further details see above]. The is expressed in the fact that solids of the same chemical composition often have quite different ones physicochemical properties and a different order of magnitude Show responsiveness as an expression of this higher potential energy content [Heinicke, G .: Physico-chemical investigations of tribomechanical processes. In: Thiessen / Meyer / Heinicke, all other information see above]. The increase in mechanical machining that can be achieved Responsiveness shows that the relative and absolute increase in reaction rate like the course of the reaction in individual reactions is extremely different and not only  from the physical and chemical properties of solids, but to a large extent also depends on the type and intensity of the mechanical processing. A tribochemical Reaction is divided into four phases, the reaction in the unprocessed state, the response, Driving response and the resting response.

For tribomechanical investigations, the processing principles are e.g. B. available the stress between two surfaces (ball mill, vibratory mill) and the stress freely moving parts on a surface or with each other (oscillating pot, vibrating grid, pin mill, Jet equipment, rotary tube roller, down tube mill).

Last but not least, geochemical has a technical significance Problems. For example, natural apatites have a very low solubility in neutral and alkaline substance systems, which results in a low nutrient supply if these as Fertilizers are used for plants. An increase in solubility and thus the Improvement of the fertilizer effect can, however, be achieved in that a Fine grinding of the minerals is made. A way to create a structural Disorder and thus the significant increase in solubility is due to the tribomechanical Activation of natural apatites given [Heinicke, G .: Tribochemistry. Akademie publishing house, Berlin 1984].

As a further technical example of influencing chemical reactions through tribomechanical preactivation, vibratory grinding of cement should be mentioned here. According to R. Schrader and B. Hoffmann: Change in the reactivity of solids through previous mechanical processing. [In: V. Boldyrev, K. Meyer (ed.): Solid State Chemistry. Contributions from research and practice. VEB Deutscher Verlag für Grundstoffindustrie, Leipzig 1973], the setting ability of cement, ie the strength that can be achieved with it, is based on the hydration of its crystal phases. The mechanical activation of cement enables a significant increase in the strength of the hydrated mineral binder [PA Rehbinder: vibratory grinding, the most effective modern fine grinding method. Stroitel. mat. 2 (1956) 8-10; AS Pantelejew: Use of vibration grinding in the building materials industry. State Publishing House for Building Science, Moscow 1967; L. Opoczky, B. Beke: Structural changes in clinker grinding to extreme subtleties. Cement Lime Gypsum 20 (1967) 267-270; G. Knape, H. Schumann, W. Koelling, R. Schrader, H. Hennek: Contribution to Vibroactivation of Cement. Silicate Technology 18 (1967) 388-394; Z. Bruthans: conference room 101 (1968) 106;]. The standard compressive strength σ _D (28-day value) of hydrated Portland cement PZ 400 is brought to particle sizes <10 µm by prior vibratory grinding of the cement (see author group: Mechanical Process Engineering II. VEB German Publishing House for Basic Industry, Leipzig 1979 ), which leads to an increase in strength from 475 kg-cm ^-2 to 560 kg-cm ^-2 in the case of mechanically activated cement in the case of hydrated cement. In the case of cements of lower quality, such as PZ 225, the effect that can be achieved by activation is even greater.

Since cement is a mixture of different mineral phases, quantitative fine structure investigations cannot be carried out using the methods used for solids. In order to justify the increased hydration ability of cement, its most important individual phases such as tricalcium silicate C₃S, dicalcium silicate β-C₂S and γ-C₂S, tricalcium aluminate C₃A, dodecacalcium heptaaluminate C₁₂A₇ and tetracalcium aluminate ferrite C₄AF were activated and batchwise activated in a solid state, Schrader, H. Schumann: On the change in cement and its individual phases through mechanical activation and storage. Silicate Technology 22 (1971) 344-348]. The simplified schematic representation of the primary particle size λ and the lattice disturbance u _{x of} the individual phases essentially establish the course of the cement strength with the grinding time. Lattice distortion was not found. The specific surface only approximates the cement strength at the beginning of the grinding process.

An increased rate of hydration is after vibratory milling of CaO-SiO₂-Ge mix [G.J. Loggonow, P.A. Rehbinder, W.F. Abposenkowa: interaction of Calcium hydroxide with sand of different dispersity at normal temperatures (Orig. Russian). Kolloidnÿ Zhurnal 21 (1959) 442-448], MgO [D.N. Polubojarinow: Fireproof Mater. (USSR) 26 (1961) 80] and CaO [R. Schrader, B. Hoffmann, H. Plänitz, J. Henneberger: About activated Calcium oxide. Cement-Lime-Gypsum 23 (1970) 194-199]. The lime-sand activation is on an industrial scale for the production of the building material silicalcite [J. Hint: Basics of making Silicalcite products. Moscow / Leningrad 1962] was applied.  

Studies of the impact processing of crystals at low temperatures have shown that according to the kinetic energy supplied different levels of plastic Deformation and cracking result. While with small impact energies the destruction in the Crystal surface remain limited to the immediate contact area, leads to an increase in Energy to form dislocations. With the energy of a steel ball of 2 mm in diameter and Approximately 4 cm drop height, screw sliding bands are almost exclusively formed. These are in (110) slip planes that are at an angle of 45 ° to a (001) surface. The removal of the deformed layers show a decreasing distance from the surface Dislocation density, which first decreases in the center, only to a depth of about 130 µm individual glide lines are recognizable [Meyer, K .: Energetically excited states in trobomechanical Processes. In: Thiessen / Meyer / Heinicke, all further details see above].

When investigating the plastic deformability of MgO crystals under stress a rolling ball also caused high dislocation densities, caused by cutting two Sliding planes, measured at a depth at which the maximum is according to Hertzian shock theory calculated shear stress occurs [Amateau, M.F .; Spretnak, J.W .: Plastic deformation in magnesium oxide crystals subjected to rolling-contact stresses. Journal of Applied Physics 34 (1963) 2340-2345].

Hard coal filter ash used for the production of high-performance concrete [Khatri, R.P .; Sirivivatnanon, V .: Effect of different supplementary cementitious materials on mechanical properties of high performance concrete. Cement and Concrete Research 25 (1995) 209-220], by chemical activation can be changed in its crystalline structure so that this treatment affects the formation of the mineral phases of the hydrating mineral binder and thus improved properties of the material result [Shi, C .; Day, R.L .: Acceleration of reactivity of fly ash by chemical activation. Cement and Concrete Research 25 (1995) 209-220].

The object of the invention is to utilize pure waste from silicate to make mineral demolition materials from buildings without affecting the known ones thermal processes such as burning or melting or the classic mechanical Process such as the production of concrete gravel to make a contribution in the sense of  Circular economy and waste law, whereby building rubble is defined as a secondary raw material for which recycling should be considered; So it's ultimately about the economy a pure high quality secondary raw material or one for the production of To provide suitable materials for recycling building materials.

The object is achieved in that high-quality secondary raw materials made from pure varieties silicate-mineral and pre-crushed demolition materials from buildings are produced, by according to the invention by tribomechanical and / or tribochemical treatment in one more reactive, activated state.

According to the method, a good with mechanically and / or chemically induced is produced Changes in the crystal structure or structure and as a result of this treatment change the previously known material properties and finally a fabric is created that has a high quality Represents secondary raw material.

The tribomechanical and / or tribochemical treatment of the processed Demolition material takes place in devices of material shredding by impact and / or friction a gas and / or liquid phase to form particles with a diameter in the Limits, based on the maximum value in the frequency distribution, of 0.1 to 30 μm, preferably in the range of 0.7 to 3.0 µm.

Vibration and ball mills are used in particular as devices for particle size reduction.

Silicic-mineral demolition materials include pre-shredded materials to understand fired bricks or roof tiles or asbestos cement slabs.

The invention will be explained in more detail with reference to exemplary embodiments, without thereby in its Restrict scope.

example 1

Brick chippings are turned into fine material using a vibrating mill in air at normal pressure with a grain diameter in the range of 1 to 10 µm. This brick flour shows latent  hydraulic properties with which after the addition of a synthetic pore solution of the hydrated Portland cement, d. H. 42 g / l KOH + 8 g / l NaOH + cold saturated with Ca (OH) ₂, cement-like Compressive strengths can be achieved. The product obtained in this way has the same strength properties Hydration product of ground blast furnace slag comparable.

In contrast, conventional brick flour as well as tress, tuff and Hard coal fly ash is classified in the group of non-hydraulic substances (puzzolans), which alone have no hydraulic properties [Hennig, O .; Knöfel, D .: Building materials chemistry. Bauverlag GmbH, Wiesbaden and Berlin 1989, p. 115]. Your chemical composition or location in the Three-component system lime-silica-alumina can be made from [Kaminsky, W .: Zement. Publishing house of Theodor Steinkopff, Dresden and Leipzig 1950, p. 4]. Such brick flour with one specific surface, which corresponds approximately to that of the cement PZ 45 F, however allows for Fresh mortar production, if it replaces 20% of Portland cement, better workability of the mortar containing brick flour, however, the compressive strength (28 d value) of Compared to pure Portland cement significantly back [Müller, A .: recycling of Masonry materials in mortars and concretes. Building material recycling + landfill technology 11 (1995) 11, pp. 4-9].

Example 2

Made from asbestos cement, a material made from Portland cement and the mineral chrysotile in Ratio of about 9: 1, using a ball mill in the presence of water (Wet grinding) a very fine ground material with a grain diameter in the range from 0.6 to 2.0 µm produced. The mechanically treated asbestos cement has a chemical similar to cement Composition, without it being possible to detect fibers. Such a thing Grist can be used, for example, in the safe production of cement raw meal mixtures Starting material can be used.

Claims (1)

Process for the production of high-quality secondary raw materials from unmixed silicate-mineral and pre-shredded demolition material from buildings, characterized in that they are brought into a more reactive, activated state by tribomechanical and / or tribochemical treatment by the processed demolition material in devices for material shredding by impact and / or friction in a gas and / or liquid phase to form particles with a diameter in the limits, based on the maximum value in the frequency distribution, of 0.1 to 30 μm, preferably in the limits of 0.6 to 3.0 µm.