RU2039107C1 - Method for rendering harmless chromium bearing wastes from galvanization - Google Patents

Abstract

FIELD: rendering harmless chromium bearing wastes. SUBSTANCE: temperature in reaction area of reducing is increased step-by-step. At the first step temperature in reaction area is increased up to evaporation temperature of the most difficultly evaporated metal-impurities, preferentially, toxic metals and removing gas flow from reaction area. After complete evaporation of toxic metal- impurities, temperature in the reaction area is increased at the second step up to the temperature below melting temperature of an alloy generating upon completion reducing oxides containing in precipitate. In so doing, volume of carbon bearing metal placed directly in reaction area is set lower than carbon amount required for full reducing the precipitate. Carbon shortage in reaction area is make up by feeding additional reducing agent, preferentially, gaseous carbon bearing reducing agent, by introducing it into gas flow pumping through reaction area using closed loop before flow entering the area. In so doing, gas flow at the outlet of reaction area is cooled down to condensation temperature of the most volatile vapor among toxic metal-impurities being reduced. Gas flow temperature is adjusted to initial one after removing metal-impurities. EFFECT: rendering harmless chromium bearing wastes. 1 dwg

Description

 The invention relates to the processing and disposal of industrial wastes, preferably chromium-containing electroplating wastes.

 A known method of neutralizing chromium-containing wastes of galvanic production, including passing them through an electrolyzer with anodes of iron or aluminum. Under the influence of direct current, the anode ions pass into the solution and, as a result of hydrolysis, form water-insoluble hydroxides acting as a coagulant. In the electrolyzer, processes of chromium reduction, coagulation and separation of the formed precipitate occur, followed by clarification of the water from the suspension in the sump. The disadvantage of this technical solution is its lack of safety (allocation of explosive gas mixtures during electrolysis), the need for bulky equipment and an insufficiently appropriate process scheme in which some components are bonded to form other, albeit less toxic ones.

 There is also known a method of neutralizing chromium-containing electroplating wastes, including their dehydration and subsequent reduction of metal-containing oxides of the precipitate by thermal exposure to them in the presence of a carbon-containing reducing agent. The disadvantage of this technical solution is the insufficient complete extraction of chromium from the waste (about 85% of the chromium contained in the precipitate is extracted). In addition, in the presence of oxides of toxic metals, such as cadmium, their recovery is inevitable, thus, additional operations will be required to clean the resulting product from toxic impurities.

 The problem to which the invention is directed, is to increase the degree of extraction of chromium contained in the precipitate of chromium-containing electroplating waste, with a high degree of utilization of all components of the waste and high-quality binding of the products of neutralization of precipitation, eliminating their uncontrolled distribution.

 The technical result obtained by carrying out the invention is expressed in the fact that in the process of neutralizing the sludge from the galvanic production waste, a material is produced that is suitable for use in powder metallurgy as a starting product, free of toxic impurities and characterized by a high degree of homogeneity.

 The problem is solved in that the method of neutralizing chromium-containing electroplating wastes, including the neutralization and subsequent reduction of metal-containing sludge oxides by thermal exposure to them in the presence of a carbon-containing reducing agent, differs from the known methods in that the temperature in the reduction reaction zone is increased in stages, at the first stage, the temperature in the reaction zone is brought to the evaporation temperature of the most difficult to evaporate from the reduced metal impurities, preferably toxic metals, with the removal of the gas stream from the reaction zone, after the complete evaporation of toxic toxic metals in the second stage, the temperature in the reaction zone is raised to a temperature lower than the melting temperature of the alloy formed upon completion of the reduction of the oxides contained in the precipitate, while the volume of carbon-containing material placed directly in the reaction zone, set the smaller the amount of carbon required to completely restore the precipitate, and the lack of carbon in the reaction This zone is compensated by introducing an additional reducing agent into it, preferably a gaseous carbon-containing reducing agent, by introducing it into the gas stream pumped through the reaction zone in a closed cycle before entering it into the latter, and the gas stream at the outlet of the reaction zone is cooled to the condensing temperature of the most volatile toxic metal impurities and after removal of metal impurities, the temperature of the gas stream is brought to the original.

 The drawing shows a diagram of an installation that provides the implementation of the method.

 The drawing shows the main thermal furnace 1, the refrigerator 2, the source of the gas mixture 3 (fan), the additional thermal furnace 4, the carburetor 5, the circulation channel 6, the carbon dioxide content indicator sensor 7, the gate valve 8 at the inlet and outlet of the refrigerator 2, the bypass channel 9 In addition, the direction of movement of the gas mixture 10 in the installation is shown.

 The claimed method is as follows. Liquid waste from galvanic production (metal-containing oxides) is dehydrated using one of the known methods, for example, mechanical, using horizontal screw centrifuges and subsequent drying. Further, in a known manner, for example by chemical analysis, the chemical composition of the precipitate is determined and the presence (or absence) of impurities of toxic metal oxides, the presence of which in the final product is undesirable, is detected. Then the precipitate is mixed with carbon (in the form of graphite, charcoal, etc.), the amount of which is taken to be less than the amount that is sufficient to completely restore the precipitate (but not less than the amount of carbon required for the reduction of toxic metal oxides). The raw material thus prepared is placed in a container, which is introduced into the thermal furnace 1, preferably a passage. The inlet and outlet of the furnace 1 are connected by a circulation channel 6, including a refrigerator 2, a fan 3 connected in series, an additional thermal furnace 4 connected to a carburetor 5 (a source of gaseous carbon-containing material). In this case, the output of the additional thermal furnace 4 is associated with the input of the thermal furnace 1.

 The thermal furnace 1 is heated to a temperature that ensures the reduction of toxic metal oxides contained in the dehydrated sludge (it is advisable that the temperature in the reaction zone correspond to the evaporation temperature of the most difficult to evaporate from the reduced toxic metals).

 At the final stage of this stage, in the reaction zone are pairs of reduced non-toxic metals that are chemically less active than toxic, and a mixture of metal oxides are chemically more active than toxic with residues of unreacted carbon-containing material.

 By turning on the fan 3 in operation, the gas mixture located in the reaction zone (in the furnace muffle) is set in motion through the circulation channel 6. When the gas mixture passes through the refrigerator 2, it is cooled to the condensation temperature of the vapors of the most volatile of the reduced toxic metals (it is advisable that the channel for passing the gas mixture through the refrigerator be removable, i.e., quickly replaceable). The metal vapor contained in the gas mixture condenses, deposited on the walls of the gas inlet channel of the refrigerator 2. Next, the gas mixture, "cleaned" of toxic metal vapors, enters an additional thermal furnace 4, where its temperature is again raised to a temperature maintained in the reaction zone. After that, the gas mixture is returned to the reaction zone (in the thermal furnace 1).

 As the carbon located in the reaction zone is consumed (judged by a sensor 7 for increasing the carbon dioxide content in the outgoing zone of the gas mixture), an additional volume of carbon, preferably in the form of a carbon-containing gas, is supplied to the gas stream returned to the reaction zone. It is advisable to carry out the reduction of carbon dioxide to oxide, for example, by passing carbon dioxide in contact with the heated carbon-containing material.

 The indicated (by gas flow circulation) is repeated until the process of removal of toxic metals is completed, after which the gas passage of the refrigerator is replaced with a new one. Then, the temperature in the reaction zone is raised to a temperature that ensures the reduction of chromium from its oxides present in the precipitate; the upper temperature limit is limited to a level that precludes melting of the entire volume of the alloy formed in the reaction zone.

 As a result of this, upon completion of the reduction process, a granular material will be in the reaction zone, each grain of which is an alloy of metals reduced from metal-containing oxides of the precipitate.

 PRI me R. The slurries of the galvanic production of the Vladivostok Tool Plant are used, obtained after the galvanic and flushing baths of the thermal compartment, which are dehydrated by means of a vacuum filter.

 Chemical analysis showed the presence of iron, chromium, cadmium and zinc oxides in the sediment, in the presence of small amounts of molybdenum and tungsten.

 The sludge neutralization process is carried out on a plant that includes the main thermal furnace, a through heat furnace of the SUOL-0.25 1 / 12.5 I1 brand with a quartz muffle with a diameter of 40 mm, a refrigerator made in the form of a cartridge containing copper cooled inserts, a conventional fan was used desktop fan, upgraded as follows: on the fan shaft, passed through the wall of the circulation channel, there is a worm gear drive wheel, the worm wheel of which is located inside the channel with rotation around the longitudinal axis of the channel, while the worm wheel is equipped with blades. As an additional thermal furnace, the same continuous thermal furnace was used. The muffle of an additional thermal furnace filled with charcoal was used as a carburizer.

A mantle of dehydrated sludge mixed with graphite in a weight ratio of 9: 0.5 is introduced into the muffle of the main thermal furnace, in a ceramic container. The first stage of recovery of metal oxide precipitate is conducted at a temperature of about 800-850 ^C. In the cooler the gas mixture is cooled to room temperature, which ensures condensation of the cadmium vapor is deposited on the copper insert refrigerators ka.

Then turn off the operation of the refrigerator (8 valves) respectively include work bypass passage 9 that supplies the gas flow past the cooler 2. Then, the temperature in the reaction zone is maintained at a level of 1000-1200 ^{° C} for 2-2.5 h until complete reduction of all metal-containing oxides.

Claims (1)

 METHOD FOR TREATING CHROMIUM-CONTAINING WASTES OF THE GALVANIC PRODUCTION, including their dehydration and subsequent reduction of metal-containing oxides of the precipitate by thermal exposure to them in the presence of a carbon-containing reducing agent, characterized in that the temperature in the reaction zone of reduction is increased in stages, at the first stage, the temperature is brought to the reaction temperature to the temperature of difficult to evaporate from reducible impurity metals, preferably toxic metals, with removal a gas stream from the reaction zone, after the complete evaporation of toxic metal impurities in the second stage, the temperature in the reaction zone is raised to a temperature below the melting point of the alloy formed upon completion of the reduction of the oxides contained in the precipitate, while the volume of carbon-containing material placed directly in the reaction zone, set less of the amount of carbon required to completely restore the precipitate, and the lack of carbon in the reaction zone is compensated by supplying an additional but a reducing agent, preferably a gaseous, carbon-containing reducing agent, by introducing into the gas stream pumped through the reaction zone in a closed cycle before introducing it into the latter, moreover, the gas stream at the outlet of the reaction zone is cooled to the condensation temperature of the most volatile vapors from the reduced toxic impurity metals and after removal of metal impurities, the temperature of the gas stream is brought to the original.

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