RU2056367C1 - Method and device for sewage treatment of chromium and heavy ferrous metals - Google Patents

Abstract

FIELD: sewage treatment. SUBSTANCE: method involves forcing sewage through a reducing material constituted by machining waste of alumo-magnesium alloys, e.g. duraluminium mixed with iron chips. The device for realization of the method may be made in two embodiments. In the first one it consists of a cylindrical casing with circular chambers arranged so as to make a labyrinth in which case the chamber walls must be faced with iron and duraluminium sheets as an imperative requirement. In the second embodiment the device comprises a cylindrical casing and a pipe in the center, both provided with hydraulic nozzles uniformly spaced over the perimeter of casing and pipe. The casing walls are faced with sheet iron inside. EFFECT: higher efficiency of treatment achieved by simplification of the process. 7 cl, 2 tbl, 2 dwg

Description

 The invention relates to the field of wastewater treatment containing hexavalent chromium and heavy non-ferrous metals, and can be used in industries where, under the conditions of the process, it is possible to reuse purified water or dump it into open water bodies.

 Currently, chemical, electrochemical and ion-exchange methods are used to treat wastewater from metal ions.

 Electrochemical and ion-exchange methods provide a high degree of wastewater treatment, but require large capital and operating costs due to increased energy consumption, high cost of ion-exchange materials and the complexity of treatment equipment. Therefore, these purification methods are not effective enough, for example, in the recycling water supply of metallurgical and chemical enterprises, as well as with large flows of wastewater.

 Chemical wastewater treatment methods are based on the use of various reagents and the formation of sparingly soluble compounds with ions of recoverable metals.

Known process for purifying waste water from heavy metal ions [1] comprising administering ferrous iron, heating to 60-80 ^{° C,} continuously introducing oxidant gas and mixing the heated alkaline reagent containing ammonium ions and hydrogen. In this case, the components are introduced in strictly specified ratios.

 The disadvantage of this method is the difficulty of separating the resulting precipitate from the solution due to its high alkalinity.

A known method of wastewater treatment from heavy metal ions with milk of lime, which is introduced under a pressure of 4-5 atmospheres [2]
The disadvantage of this method is the need for strict control of pH values, deviations from which lead to a violation of the entire cleaning process. In addition, the construction of bulky wastewater treatment plants is required due to the large amount of precipitation formed. All this taken together reduces the effectiveness of the cleaning method.

 A known method of purification of wastewater from chromium [3] including the recovery and evolution of chromium by a solution of sulfur in hydroxide. Ammonium, sodium, calcium and barium hydroxides are used as hydroxides.

The disadvantage of this method is the high cost and deficit of the reagents used NaOH, Ba (OH) ₂ , as well as secondary pollution of wastewater with ammonia.

 Closest to the claimed method is a method for wastewater treatment of chromium compounds [4] which involves contacting water by filtration through a reducing agent, which is used as a mixture of aluminum chips with iron powder in a certain ratio.

 However, this method cannot be applied for wastewater treatment from heavy non-ferrous metals (except copper), in particular from zinc and nickel. The use of iron powder as a reducing agent on an industrial scale is difficult, since it oxidizes very quickly in air.

A device for wastewater treatment, containing a housing with a conical bottom, is installed inside the housing precipitation elements made in the form of spiral boxes [5]
A disadvantage of the known device is the difficulty of manufacturing precipitation chambers in a spiral. In addition, in a spiral design with equal volumes of incoming water, its contact time with a reducing agent is not enough due to acceleration when the solution passes through the spiral, therefore, in this case, a significant increase in the size of the treatment device is required.

 The technical problem solved by the invention, the development of a method that provides high efficiency of wastewater treatment from chromium and heavy non-ferrous metals of copper, zinc, nickel, tin due to the simplification of the process, the use of cheap and affordable reagents, reduction of energy consumption, as well as the creation for this purpose device design, characterized by ease of manufacture and maintenance.

 To solve the problem in a method of treating wastewater from chromium and heavy non-ferrous metals, including contacting with a metal reducing agent, according to the invention, the waste of mechanical processing of aluminum-magnesium alloys, for example duralumin, mixed with iron chips is used as a reducing agent, and contacting is carried out by passing waste water through a reducing agent.

 Along with the mechanical processing of steels, waste of any aluminum-magnesium production, including scrap of worn aircraft bodies, can be used as a cleaning material-reducing agent, which in comparison with the known reducing agents provides a significant reduction in the cost of the process with the same degree of cleaning. The ratio of aluminum and magnesium in the alloy is any.

 The use of iron chips with waste aluminum alloys with magnesium as a precipitating agent-reagent provides the removal of heavy non-ferrous metals from wastewater together with chromium due to the presence in the alloy of magnesium, which has a more negative electrical potential than iron and aluminum. In addition, the proposed method allows wastewater treatment in a wider pH range due to the amphoteric properties of the alloy, i.e. both in acidic and alkaline environments.

 The proposed method can be implemented in one embodiment of the device.

 According to the first embodiment, the inventive method can be implemented in a device comprising a vertical cylindrical body with a conical bottom and precipitating elements located in the housing, which according to the invention differs in that they are made in the form of annular chambers, while the walls of the housing are lined with aluminum sheet (duralumin) from the inside and iron (like the "Labyrinth").

 According to the second embodiment, the wastewater treatment device includes a vertical cylindrical housing with a conical bottom and a pipe located along the central axis of the housing. According to the invention, the device is characterized in that the casing and the pipe are equipped with hydraulic nozzles for spraying wastewater, evenly spaced around the perimeter of the casing and the pipe, while the walls of the casing are lined with sheet metal from the inside (like "Fountain").

 The implementation of the treatment device with annular chambers of the type "Labyrinth" provides a continuous flow of wastewater. In addition, with this design, the transportation zone increases, in which the flow of water, moving at a given speed, artificially slows down at bends, which ensures an increase in the contact time of wastewater with the reagent-precipitant.

 The walls of the chambers of the claimed device are lined from the inside with sheet metal and aluminum (duralumin) from opposite sides, which ensures the intensification of the process as a result of the formation of galvanic pairs aluminum-magnesium-iron.

 An embodiment of a device for treating wastewater with hydraulic nozzles located around the perimeter of the housing and in the center, of the “Fountain” type, provides spraying of water over the reagent-cleaner, thereby increasing the contact time of the source water with it and increasing the degree of purification. Hydro nozzles as a result of aeration provide oxygen saturation of the water, increasing the rate of formation of hydroxides of removed metals.

 The lining of the walls of the housing of the device with sheet metal, as in the first embodiment, intensifies the process as a result of the formation of galvanic pairs of iron-magnesium-aluminum.

 Figure 1 presents a diagram of a device for wastewater treatment according to the first embodiment ("Labyrinth").

 A device for treating wastewater from hexavalent chromium and heavy non-ferrous metals includes a housing 1, a conical bottom 2, annular chambers 3, walls 4 of the annular chambers, lined with sheet iron and aluminum (duralumin) from opposite sides.

 Figure 2 presents a diagram of a device for wastewater treatment according to the second embodiment ("Fountain").

 A device for treating wastewater from hexavalent chromium and heavy non-ferrous metals contains a housing 1, a conical bottom 2, a pipe 3 located on the central axis of the housing, and a hydraulic nozzle 4.

 The method is as follows.

Wastewater containing chromium, copper, zinc, nickel, tin, etc., is pre-filtered to remove mechanical suspensions, and then fed to metal ions. Their removal is carried out in a wastewater treatment plant, into which waste is loaded from the machining of an aluminum-magnesium alloy and steels in the form of shavings or scrap of various sizes from 10 to 50 mm ² . The amount of material loaded depends on the dimensions of the device, but a prerequisite is a ratio to the solution in which the cleaning material rises above the original solution.

 The dimensions of the treatment device, in turn, depend on the required degree of water purification required for subsequent use.

 At the outlet of the treatment plant, wastewater is analyzed for the residual content of chromium ions and heavy metals.

 Examples of the method are presented in tables 1 and 2. From the above data it is seen that the inventive method can be carried out at any pH value and provides any desired degree of purification. It can also be seen from the given specific examples that the necessary and sufficient degree of purification will be achieved at all linear water flow rates not exceeding 1.65 cm / sec, after which the water can be reused for the plant’s recycling water supply.

 The proposed method of wastewater treatment can be carried out in two versions of the device.

 The device according to the first embodiment of the type "Labyrinth" works as follows.

 The annular chambers 3 located in the housing 1 are filled with lumpy scrap metal of an aluminum-magnesium alloy mixed with iron shavings ≈ 1: 1. The initial wastewater at a factory speed flows through the pipe into the peripheral chamber and passes through the remaining ten annular chambers uniformly filling the free space between pieces of scrap.

 When flowing through annular chambers filled with scrap metal of an aluminum-magnesium alloy with iron chips, metal ions in wastewater react and precipitate in the form of hydroxides. Purified water with suspended hydroxides exits through the conical bottom of the body, which has a ring-shaped recess in the center with two outlet openings 5.

 The device according to the second embodiment of the type "Fountain" works as follows.

 The initial wastewater flows at an available speed into the housing 1, filled with scrap metal of an aluminum-magnesium alloy with iron shavings, through hydraulic nozzles 4 located along the perimeter of the housing and in the center. With the help of hydraulic nozzles, wastewater is sprayed over the material in the housing. When they contact, the interaction of impurities with aluminum, magnesium and iron with the formation of metal hydroxides, and purified water is removed through the outlet in the center of the conical bottom 2 of the housing 1.

 The use of the claimed inventions in comparison with the known ones can significantly increase the efficiency of wastewater treatment as a result of the continuity of the process and the elimination of additional water pollution by secondary chemicals, as well as reducing labor costs, since the claimed devices do not require personal service. In addition, the proposed method allows the cleaning process in a wider pH range, normalizing it in the range of 6-8 from both pH ≈ 2 and pH> 14.

Claims (6)

 1. A method of treating wastewater from chromium and heavy non-ferrous metals, comprising passing wastewater through a metal reducing agent based on aluminum and iron, characterized in that the waste reducing agent is used for machining aluminum-magnesium alloys mixed with iron shavings. 2. The method according to p. 1, characterized in that the particle size of the reducing agent is 10 to 50 mm ² .  3. The method according to p. 1, characterized in that the linear velocity of the water flow does not exceed 1.65 cm / s  4. The method according to p. 1, characterized in that the reducing agent is taken in an amount that ensures its elevation above the purified water.  5. A device for treating wastewater from chromium and heavy non-ferrous metals, comprising a vertical cylindrical body with a conical bottom, characterized in that the body is equipped with annular chambers arranged in such a way that they form a labyrinth between themselves, while the walls of the chambers are lined with sheet metal and duralumin from opposite sides.  6. A device for treating wastewater from chromium and heavy non-ferrous metals, comprising a vertical cylindrical body with a conical bottom and a pipe located along the central axis of the body, characterized in that the body and pipe are equipped with hydraulic nozzles evenly spaced around the perimeter of the body and pipe, the walls the casings are lined with iron inside.

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