EP1219324A2 - Method for elimination of halogenated and non halogenated waste - Google Patents

Abstract

Process for disposing halogenated and non-halogenated waste comprises reacting the waste with products containing metal oxide with exclusion of oxygen at 800-1100 degrees C.

Description

The present invention relates to a method for the disposal of halogenated and non-halogenated waste.

Substituted, especially halogenated hydrocarbons such as for example in carbon tetrachloride, chloroform, methylene chloride, tetra- and Trichlorethylene, tetrachloroethane, PCB etc. but also in PVC or Polyvinylidene chloride are more or less after use problematic toxic or special waste that needs to be disposed of.

Substances that are highly toxic to the environment and humans, such as halogenated substances Compounds, especially polyhalogenated substances such as e.g. PCBs or TCDD / TCDF (dioxins / furans) cannot be easily recycled and must be disposed of in an environmentally friendly manner.

Disposal takes place either by landfill or by incineration high seas or in the country in high temperature furnaces with one Excess air.

The energy requirement is not insignificant in many cases, since not only that eliminating substances evaporated and to the required decomposition temperature heated, but also enormous amounts of air have to be heated. Doing so either, as with combustion at sea, pollution of the The atmosphere and the risk of acid rain are accepted Extremely expensive air pollution control systems required.

DE-A-33 13 889 describes a method or an apparatus for Removal of poison and hazardous waste known, in which the toxic Waste materials with an electrically conductive substance, in particular in the form of Iron powder and / or coke mixed and placed in an induction furnace Decomposition temperature of the toxic and / or special waste to be disposed of brought.

US-A-4,435,379 describes a process for the decomposition of chlorinated Hydrocarbons with metal oxides with the aim of all carbon atoms in To transfer carbon oxide. It is important to use elemental chlorine To provide conversion of hydrogen groups to HCI. The must total ratio of chlorine to hydrogen groups is at least 1: 1, to be able to produce metal chloride.

US-A-4,587,116 describes a similar process in which nitrogenous waste can be disposed of. The heating takes place also from the outside and not from the inside.

US-A-4 451 907 discloses a process for the removal of chlorinated organic compounds. First, the chlorinated organic Compounds evaporated in a molten salt furnace, and then to one Reactor led. The chlorinated, organic Compounds heated to 800 to 1200 ° C, in the presence of aluminum oxide and reactive carbon, and consequently decomposes. Nitrogen is used as a carrier gas used to evaporate the chlorinated organic compounds Lead the molten salt furnace to the reactor.

EP 0 306 540 describes a process for the production of energy from substituted hydrocarbons, such as those used as CCl ₄ , CHCl ₃ , C ₂ H ₂ Cl ₄ , PCB,

PVC, polyvinylidene chloride, etc. are present in pure or bound form. The waste material is thermally decomposed in an inductively heatable reactor in the presence of a metal oxide which is difficult to smelt and an electrically conductive material, for example electrode coke or electrographite, and in contact with water vapor at temperatures between 800 and 1,100 ° C. A proportion of the metal oxide that corresponds to the chlorine content of the waste materials is converted into volatile metal chloride. A portion of the released carbon is converted into carbon monoxide and the portion of the carbon that does not react with the metal oxide is converted into water gas (CO + H ₂ ) with the aid of a stoichiometric amount of water vapor.

The object of the present invention is to develop a method that allowed various halogenated and non-halogenated waste materials to dispose of in an environmentally friendly manner.

This object is achieved according to the invention by a process for the disposal of halogenated non-halogenated waste materials, in which the halogenated and non-halogenated waste materials are mixed with TiO ₂ , SiO ₂ , CaO and / or Fe ₂ O ₃ or a mixture thereof with the exclusion of oxygen at temperatures of 800 ° C to 1100 ° C can be implemented.

The procedure described here is for environmentally neutral recycling of halogenated and non-halogenated waste materials.

The volume of waste used is largely reduced, so that as little residue as possible and as much as possible of Metals / metal compounds is obtained. When implementing a aiming for a positive energy balance.

In a preferred embodiment of the method, carbon-containing, halogenated waste materials implemented.

In an advantageous embodiment of the method, carbon dioxide is used as Fluidizing gas added.

Furthermore, the reactor can also use carbon in the form of graphite and / or Coal are charged.

Various metal oxide-containing waste materials, such as silicon-containing residues from the metalworking industry, filter dusts, fly ash, flying sands, pile of heaps, electroplating sludge, slag, slate residues etc. can also serve as reaction partners. Simple quartz sand, which consists of approximately 98% silicon dioxide (SiO ₂ ), is the simplest possible material that can be used for the implementation.

All of the above materials are distinguished by the fact that they contain a relatively high content of halogenatable metal oxides (CaO, SiO ₂ , TiO ₂ , Fe ₂ O ₃ etc.).

This has the advantage that for so far not with economic means substances containing smeltable metal oxides are now useful Find application.

Halogenated waste materials can be solvents such as: Carbon tetrachloride, chloroform, methylene chloride, tetra- and trichlorethylene, Tetrachloroethane, coolants or refrigerants, PCB, pesticides, fungicides and herbicides, halogenated plastics such as Use PVC.

A proportion of the metal oxide that corresponds to the chlorine content of the waste materials is converted into metal chloride by the above-mentioned process. Ecologically and economically valuable metal chlorides are formed, with silicon and titanium tetrachloride (SiCl ₄ , TiCl ₄ ) being particularly preferred products.

Among other things, Used oils, lubricants, greases, varnishes, paints, tars, waxes, No plastics, coolants and solvents, brake fluid or the like halogenated substances and materials are disposed of.

The thermodynamically preferred formed under these process parameters

The reaction or reaction products are primarily gaseous hydrogen (H ₂ ) in addition to lower percentages of methane (CH ₄ ).

The formation of environmentally hazardous or polluting, gaseous substances such as carbon monoxide (CO), and the carbon dioxide (CO ₂ ) known as so-called greenhouse gas, is negligible under the preferred reaction conditions. Only at temperatures above 1100 ° C can CO or CO _{2 be} formed by chemical decomposition processes.
The implementation takes place in a fluidized bed reactor. This can either be made of special ceramics, silicon carbide (SiC) or specially alloyed steels.

The reactor can be brought to the necessary operating temperatures either by using electrical heating elements (eg heating half-shells) or by using induction heating. The temperatures required for the implementation are in the range of 800 ° C to 1100 ° C. The reaction itself takes place with the exclusion of oxygen. Carbon dioxide (CO ₂ ) is used as the fluidizing gas.

The halogenated compounds are in their high temperatures the simplest components are broken down in the case of chlorinated hydrocarbons hydrogen chloride, hydrogen, alkanes and chlorine gas are formed. The Chlorine gas and the hydrogen chloride serve as chlorinating agents for the metal oxide-containing products or waste. Products of this chlorination reaction are the thermodynamically preferred metal chlorides.

In addition to the chlorides, hydrogen and carbon monoxide are formed, which can be used as synthesis gas either for the production of electrical energy or for other chemical syntheses, such as methanol synthesis. 2 H ₂ + CO ⊗ CH ₃ OH

Reaction equation 1

The carbon dioxide (CO ₂ ) used as fluidizing gas is completely converted to carbon monoxide (CO) by reaction with the carbon of the decomposed hydrocarbons and by an additional bed of carbon or graphite in the head of the reactor.

In this context one speaks of the so-called BOUDOUARD reaction: CO ₂ + C 2 CO

Reaction equation 2

The formation of environmentally harmful compounds such as dioxins, furans or, for example, phosgene (COCl ₂ ) is extremely unlikely under the prevailing reaction conditions.

All halogenated metal compounds produced are initially in gaseous form. Depending on the starting material, solid cooling, i.e. crystalline metal compounds can be obtained, or by condensation metal compounds liquid at low temperatures.

The purity of these compounds is 96% and can e.g. by a fractional distillation, or rectification called, still be improved.

Various configurations of the invention will now be described below of the accompanying figures. It shows:

Fig. 1: a diagram of the plant for the disposal of halogenated waste.

1 shows a feed line 1 for the halogenated waste materials, a feed line 2 for products containing metal oxide, and a line 3 for discharging unreacted materials 3. A fluidization gas ( CO ₂ ) blown into the fluidized bed reactor 5.

The reactor 5 is heated by means of a reactor heater 6 to a temperature between 800 ° C and 1100 ° C, so that there is a reaction between the halogenated waste and the metal oxide-containing substances in the reactor. The products formed are separated in a solids separator 7 and the solid metal chlorides, in particular FeCl ₃ , are discharged via a line 8. The remaining gases are cleaned by an activated carbon filter 9 and then compressed by a blower 10. The gases are then cooled in a cooling container 12, which has a coolant inlet 11 and a coolant outlet 13, so that the remaining metal chlorides are eliminated. It is mainly SiCl ₄ .

The gases are then fed to a condenser 15 and subjected to an alkaline gas scrubbing in a gas scrubbing column 16. The column 16 has a circulation pump 17 for the washing liquid. The remaining synthesis gas, a mixture of CO and H ₂ , is discharged via line 18 in the upper part of the gas scrubbing column 16.

Application example 1: Disposal of hydrocarbon (KW) or halogenated hydrocarbon (HKW) wastes in the presence of calcium oxide

The various feed materials, such as Oils, fats, PCBs, CFCs, Solvents or the like are dispensed via a metering device, e.g. a Eccentric screw pump, conveyed into the reaction zone. Done there suddenly a first thermal splitting of the feed materials into short-chain Hydrocarbons. The residence time of the Input materials or the resulting fission products determined.

As a rule, there is an almost quantitative split up to essentially Hydrogen and methane, the volume ratio of hydrogen to methane is clearly on the side of hydrogen. Since the melting point of Calcium oxide (CaO) is around 2500 ° C, with no large amounts synthesized calcium compounds.

In contrast, halogenated feedstocks, especially chlorinated materials reacted, then a reaction occurs between the calcium oxide and the halogen atoms of the feed materials.

Calcium chloride (CaCl ₂ ) is essentially formed as the reaction product, which remains in the reactor as slag or melt. The following reaction equation (reaction equation 1) takes into account all essential products that are formed during the disposal or recycling of a halogenated hydrocarbon. The individual products were calculated thermodynamically and verified experimentally.

reaction equation

In addition to this reaction, carbon is also in the form of fine Soot particles discharged from the reactor.

The separation from the other gaseous components hydrogen and Methane, or hydrogen and carbon monoxide (CO), takes place through Gravity separators, e.g. a high performance cyclone.

For safety reasons, the gases cleaned in this way can still be filtered using activated carbon filters be directed. Should still contain foreign matter in the process gas , these can either be through targeted condensation or through a Gas scrubbing can be removed.

In the end, usually only one made of carbon monoxide, methane and hydrogen existing synthesis gas left, which for versatile techn. Applications, so e.g. energy generation or use for chemical synthesis (Methanol synthesis) can be used.

Claims (8)

Process for the disposal of halogenated and non-halogenated waste materials, characterized in that the waste materials are reacted with TiO ₂ , SiO ₂ , CaO and / or Fe ₂ O ₃ or a mixture thereof with the exclusion of oxygen at temperatures of 800 ° C to 1100 ° C. A method according to claim 1, characterized in that the waste materials contain carbon. A method according to claim 1 or 2, characterized in that carbon dioxide is added in the method. Method according to one of the preceding claims, characterized in that carbon is added in the method A method according to claim 4, characterized in that graphite and / or coal is used as carbon. Method according to one of the preceding claims, characterized in that the halogenated waste materials, solvents such as: carbon tetrachloride, chloroform, methylene chloride, tetra- and trichlorethylene, tetrachlorethylene, coolant or refrigerant, PCB, pesticides, fungicides and herbicides, halogenated plastics such as PVC become. Method according to one of the preceding claims, characterized in that a proportion of the metal oxide which corresponds to the chlorine content of the waste materials is converted into metal chloride. Method according to one of claims 1 to 7, characterized in that used oils, lubricants, greases, varnishes, paints, tars, waxes, plastics, coolants and solvents, brake fluid or similar non-halogenated substances and materials are used as non-halogenated waste materials.

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