DE3815461C2 - Process for the treatment of contaminated soils - Google Patents

Description

The invention relates to methods for the treatment of contaminated soils.

Decontamination of soils or dumps by hydrocarbons, oil or heavy metals are contaminated is very expensive. Therefore, too suggested by processing these soils into a little or no contaminated part and separate into a part that is most of the Contains impurities in a concentrated form. The decontamination of this part is then much cheaper and easier.

From J.E. Garnett, D.L. Mitchell, P.T. Faccini "Initial Testing of Pilot Quipment for Soil Decontamination ", REP-3022, TIC-4500, DE-AC 04-76D P 03 533, U.S. Department of Energy, October 17, 1980, it is known through plutonium treated oil to treat contaminated soils by wet treatment. The fine-grained soil components with which the plutonium associated, separated from the coarser components. The bottom will first treated in a drum washer, in which dry aggregates broken open and oil washed away from gravel and coarse sand. The Wash with an aqueous NaOH solution with pH 11. For better Agitation of the slurry, the drum is equipped with small blades. The drum is provided with a sieve at the discharge, which is around 50% oversize Repels +4 mm. The undersize is placed on a sieve with a grain size of 0.5 mm sieved and the fraction repelled +0.5 mm. The fraction becomes -0.5 mm by hydrocyclonation and centrifugation into a fraction +0.05 mm and one  Fraction -0.05 mm separated. The fraction -0.05 mm is caused by flocculation and Centrifugation separated into solid and washing liquid, which are returned to the Drum washer and screening is conducted. However, this procedure does not a satisfactory decontamination of the floor.

The invention has for its object in contaminated soils or heaps to prepare as economically as possible so that as large a part as possible reusable form or safe disposal, and the Contamination can be accumulated in the smallest possible residue.

This object is achieved according to the invention by a method for Treatment of contaminated soils by agitation in water Slurry in a drum with the addition of loose chunks of the type of Grinding bodies with a net energy consumption of 4 to 16 kWh / t throughput are treated, the speed 50 to 90% of the critical speed of

, where D is the diameter of the drum in meters that comes from the drum discharged aqueous slurry by sieving into a coarser and one finer fraction is separated, the coarser fraction as a purified fraction is discharged, the finer fraction is classified, creating a coarse fraction accumulates, which is discharged as decontaminated soil, as well as a suspension which is removed as a pollutant concentrate after dewatering.

The term "floors" is used for all materials that are characterized by the Have procedures prepared, e.g. B. also for piles. The floors will vary depending Condition, before use in the drum by a scrap and stone Deposition headed. The maximum grain size for the feed is about 200 mm. The net energy consumption of the drum is on the Drum shell transferred energy, d. H. the energy consumption of the drum in filled state minus the energy consumption when empty. The net Energy consumption is related to the throughput on dry soil. Of the  optimal value for energy consumption in the range according to the invention depending on the type of soil and contaminants. It becomes empirical determined. The lower limit of the energy consumption is preferably above 6 kWh / t Throughput, because then generally better results are achieved. "D" is the Diameter of the drum in meters. Treatment of the soil in the drum takes place in such a way that there is a strong abrasion of the surfaces of the grains. In the a certain amount of energy is required Grain crushing. The screen cut also depends on the type of soil and the impurities and is determined empirically. The aqueous medium in the drum generally consists of water, preferably recycled Water from subsequent stages of the process. The screening takes place expediently on a vibrating screen with spraying with recycled Water and / or fresh water. The vibrating screen can pass through the coarse grain previous screening, e.g. B. arranged by a at the discharge of the drum Strainer basket. From the finer fraction before Desludging ferromagnetic components removed by magnetic separation will. Hydrocyclones are used to desludge the screened, finer fraction particularly suitable, the lower reaches of which are washed again before being used as cleaned soil is removed. This can e.g. B. in a spiral classifier Spray with fresh water. The drainage of the overflow of the Hydrocyclones containing the sludge can be thickened, Centrifuges or filters take place. The water from the drainage are fed back into the drum and possibly into the screening. A part of Water is led into a wastewater treatment plant. If the impurities of the Soil consisting only or predominantly of heavy metals can in this way without further treatment of the sludge suspension before dewatering cleaned soil and a pollutant concentrate are generated. When screening about 5 to 15% is obtained as clean soil. When it comes to desludging Sludge smaller than about 0.063 mm. The amount is about 5 to 15%. By the degree of desludging can influence the cleaning effect.

This object is achieved according to the invention by a method for Treatment of contaminated soils by agitation in water Slurry in a first drum with the addition of loose chunks according to Art  of grinding media with a net energy consumption of 1 to 6 kWh / t throughput are treated, the speed 50 to 90% of the critical speed of

, where D is the diameter of the drum in meters that comes from the drum discharged aqueous slurry by sieving into a coarser and one finer fraction is separated, the coarser fraction as a purified fraction is removed, separated from the finer fraction sludge as a suspension is drained and discharged as a pollutant concentrate desludged rest of the finer fraction in a second drum with addition of loose chunks like grinding media with a net energy consumption of 4 to 16 kWh / t throughput is treated, the speed of 50 to 90% of the critical speed of

is, of the second aqueous discharged from the second drum Slurry sludge separated, dewatered and second Pollutant concentrate is removed and the desludged second rest of the finer fraction is discharged as a cleaned soil after dewatering. Make the explanations for the above procedure, with the exception of the Details of the net energy consumption for the first drum and the amount of with sludge accumulation - also with this way of working. The net energy consumption in the first drum is preferably 1 to 4 kWh / t.

A preferred embodiment consists of the drum 60 being the rotational speed up to 80% of the critical speed can be used. This speed gives Particularly good cleaning effects due to the treatment in the drum.  

A preferred embodiment is that the sieving at 1 to 2 mm he follows. In many cases, this screen cut gives a good separation in the cleaned Soil and pollutant concentrate.

A preferred embodiment is that the desludged rest of the finer fraction is treated in a flotation, the foam product Pollutant concentrate is discharged and the underflow after drainage as cleaned soil is removed. When working with two cascaded drums are used to flotate the desludged Rest of the finer fraction from the first drum after its treatment in the second drum in the second drum discharged from the second drum aqueous slurry. The flotation foam product is after a Drainage discharged as a pollutant concentrate, the underflow of the flotation becomes desludged, the separated sludge of the lower reaches after a Drainage removed as a pollutant concentrate and the desludged rest of the Lower flow discharged as cleaned floor. The lowering of the lower reaches the flotation is advantageously carried out again in a spiral classifier downstream hydrocyclone. The sludge separated in the hydrocyclone becomes passed into the thickener. This way of working is particularly so with floors applied, which contain hydrocarbons and / or oil, being heavy metals also be recorded in the pollutant concentrate. Can be used as a flotation agent Collectors such as oleic acids, oleic acid derivatives, diesel oil, amines and others are used will. Despite the addition of oil, a cleaned soil is obtained that is free of Oil is or only contains very small amounts. Underflow and overflow of Flotation is expediently first dewatered in thickeners and theirs The underflows are then dewatered separately in centrifuges and filters.

A preferred embodiment is that steel balls as chunks be used and the drum with steel balls up to a maximum of 40 vol .-%, based on the idle state of the drum. Up to this Good filling results are achieved when the drum is at rest. Of the Depending on the material to be processed, the lower filling level should not be below 5 vol .-% are.  

A preferred embodiment is that 55 to 65% in the drum the steel balls with a diameter of about 20 to 30 mm and 45 to 35% Steel balls with a diameter greater than 30 to 100 mm are used will. With these proportions, very good results are achieved.

A preferred embodiment is that as a chunk of its own and / or non-natural and / or artificial lumpy material is used and the drum with up to 60 vol .-%, based on the Idle state of the drum, is filled with lumpy material. In particular type of coarse material used before the floor is used in the Drum is screened. The lower degree of filling of the drum with this material should not be less than 5% by volume. Because the lumpy material is lighter than Steel balls, the turbidity in the drum must be kept lower than at working with steel balls to get the necessary energy through the lumpy Transfer material.

A preferred embodiment is that lumpy material with a Piece size from 60 to 200 mm is used. This piece size makes good ones Results.

A preferred embodiment is that the drum on the Discharge side with a grate and discharge blades to regulate the Turbidity is equipped in the drum. This can cause the turbidity in the drum can be kept low in a simple manner.

A preferred embodiment is that steel balls and lumpy material can be used. As a result, the material can be considered as Chunks are used, and the steel balls make a bigger one Transfer of energy.

A preferred embodiment is that the addition of the chunks in the Drum is controlled so that the energy consumption of the drum remains constant. This allows constant cleaning results to be achieved in a simple manner will.  

A preferred embodiment is that the cleaned floor in one second treatment stage is treated again. This allows the Cleaning effect can be enhanced.

A preferred embodiment is that the net energy consumption the drum is set higher in the second treatment stage than in the first stage of treatment. The net energy consumption in the first Treatment level is chosen so that in the second treatment level higher net energy consumption can take place in the specified range. Thereby very good cleaning is achieved, the higher energy consumption only for a smaller part of the material is required.

A preferred embodiment is that the screening of the Drum discharged aqueous slurry into a coarser fraction larger grain size, a coarser fraction with smaller grain size and the finer Fraction. The screening is preferably carried out at around 1 mm and around 6 mm. Some floors contain wood-like components that have large proportions of contain oily residues. These components can be found in the coarser Fraction with a smaller grain size are separated and worked up separately be, e.g. B. by adding to the second drum.

A preferred embodiment is that in the drum Task material with 5 to 40% by weight of a grain size smaller than 60 µm is used becomes. It was surprisingly found that the rest Pollutant content of the purified fraction can be kept particularly low. The fine fraction can consist of the same contaminated soil substance and possibly generated by grinding beforehand, or it can also other fine-grained substances such as B. limestone, sand, marl, clay, coal, Waste coal, used activated carbon and flotation wash mountains can be added. If substances such as coal, waste coal or used activated carbon are added, the addition is preferably 5 to 20%. If other substances like limestone, Sand, etc. are added, the addition is preferably 15 to 30%. When treating the floor in two drums connected in series  takes place, the fine fraction in the first drum, in the second drum or split into the first and second drums. Preferably definitely some of the fine grain material in the second drum abandoned because there is little or no fine-grained material. The in the second drum is not made of contaminated material exist, otherwise poor cleaning will occur.

A preferred embodiment is that to adjust the Fine grain content less than 60 µm fine grain minerals are added contain at least one compound from the group SiO₂, Al₂O₃, CaO and MgO, and the amount and composition of the fine-grained substances added so is chosen that from the pollutant concentrate at a thermal Treatment creates a slag phase of the desired composition. This means that in addition to good cleaning, one for the Further processing of the pollutant concentrate required cheap Slag composition can be achieved.

A preferred embodiment is that the pollutant concentrate in a rotary kiln by thermal treatment in a pasty to liquid Slag phase is transferred and the composition of the abandoned Pollutant concentrate is selected so that a slag phase is generated, whose main constituents make up the basic mass in the range of 60 to 72% SiO₂, 10 to 30% Al₂O₃ and 5 to 25% CaO + MgO, and the Main components SiO₂, Al₂O₃, CaO and MgO together at least 60% of the dry and glow-loss-free, given to the rotary kiln Amount of pollutant concentrate, the discharged slag phase cooled and the exhaust gas from the rotary kiln is subjected to cleaning. A reappraisal of contaminated minerals through thermal treatment in a rotary kiln under these conditions is the subject of patent application P 37 18 669.8. With this method of operation, the coarser ones can be cleaned well at the same time Fraction can be achieved, the amount of processed in the rotary kiln Material is significantly reduced that contained in the pollutant concentrate Pollutants are, for. T. converted into harmless substances by combustion, the remaining pollutants become like this in the slag phase formed  included and immobilized that the slag either deposited easily or for various purposes, such as land filling, road and dam construction, Mountain offset, etc., can be used.

A preferred embodiment is that the cleaned floor with Microorganisms is added. By adding microbes and bacteria traces of organic pollutants still present in the cleaned soil, like hydrocarbons. This can be done by adding the Microorganisms or substrates impregnated with microorganisms at the end of the last spiral classifier on a drainage filter for the cleaned floor or in the event of temporary storage or after the floor has been returned respectively. In this context, nutrients for the Microorganisms in the already moist and well-ventilated prepared soil to ensure that a maximum of Post-cleaning effect is also achieved over a long period.

The invention is explained in more detail with reference to the figures.

Fig. 1 shows a one-stage treatment in a drum.

Fig. 2 shows a two-stage treatment in two drums connected in series.

Fig. 1:
The contaminated soil ( 1 ) is freed of stones and scrap on the sieve ( 2 ). The stones ( 3 ) are removed as decontaminated soil ( 4 ). The remaining contaminated soil is charged by the belt scale ( 5 ) into the drum ( 6 ). The drum ( 5 ) is equipped on the discharge side with discharge blades ( 7 ) and a sieve basket ( 8 ). Coarse grain is passed through the sieve basket ( 8 ) and discharged via ( 9 ) as a decontaminated floor ( 4 ). The discharged slurry falls through the sieve basket ( 8 ) and is directed to the vibrating sieve ( 11 ) via ( 10 ). There it is sprayed with fresh water ( 12 ) and return water ( 13 ). The coarser fraction is discharged via ( 14 ) as decontaminated soil ( 4 ). The finer fraction is passed via ( 15 ) into the magnetic separator ( 16 ), where scrap iron is separated off and removed via ( 17 ). The finer fraction is passed from the pump ( 18 ) via ( 19 ) into the first hydrocyclone ( 20 ). The overflow is conducted via ( 21 ), pump ( 22 ) and ( 23 ) into the second hydrocyclone ( 24 ). The underflows from both hydrocyclones are fed via ( 25 ) into the spiral classifier ( 26 ) and sprayed with fresh water ( 12 a). The coarse fraction is removed from the spiral classifier ( 26 ) via ( 27 ) as a decontaminated soil ( 4 ). The suspension is passed via ( 28 ) together with the overflow from the second hydrocyclone ( 24 ) via ( 29 ) into the flotation ( 30 ). The foam product is passed through ( 31 ) into the thickener ( 32 ). The underflow is passed through ( 33 ) into the thickener ( 34 ). The overflows of the thickeners ( 32 ) and ( 34 ) are fed via ( 35 ) and ( 36 ) into the return line ( 36 ). The underflow from the thickener ( 34 ) is fed into the centrifuge ( 37 ), from which the solid is discharged via ( 38 ) as a pollutant concentrate ( 39 ) and the liquid is fed via ( 40 ) into the return line ( 36 ). The underflow from the thickener ( 32 ) is passed into the hyperbaric filtration ( 41 ), from which the solid is discharged via ( 42 ) as a pollutant concentrate ( 39 ) and the liquid is fed via ( 43 ) into the return line ( 36 ). Part of the return line ( 36 ) is fed into the waste water treatment ( 44 ), part into the drum ( 6 ) and part via ( 13 ) onto the vibrating screen ( 11 ). The residue from wastewater treatment ( 44 ) is removed via (45) as a pollutant concentrate ( 39 ).

Fig. 2:
Contaminated soil ( 1 ) and water ( 2 ) are charged into the drum ( 3 ). The slurry discharged from the drum is passed over ( 4 ) onto the twin sieve ( 5 ) and sprayed with water ( 6 ) there. The coarser fraction ( 7 ) with a grain size over 6 mm is discharged as decontaminated soil. The coarser fraction ( 8 ) with a grain size of less than 6 mm and more than 1 mm is worked up separately. The finer fraction with a grain size of less than 1 mm is applied to the spiral classifier ( 12 ) via ( 9 ), pump ( 10 ) and ( 11 ) and sprayed there with water ( 13 ). The suspension containing the sludge is passed into the hydrocyclone ( 17 ) via ( 14 ), pump ( 15 ) and ( 16 ). The underflow of the hydrocyclone is passed via ( 18 ) into the second drum ( 19 ). The desludged residue discharged from the spiral classifier is also passed into the second drum ( 19 ) via ( 20 ). The suspension containing the sludge is passed from the hydrocyclone ( 17 ) via ( 21 ) into the thickener ( 22 ). Water is fed into the second drum ( 19 ) via ( 23 ). The slurry discharged from the second drum ( 19 ) is passed via ( 24 ) into the flotation ( 25 ) and is floated there with the addition of flotation reagents and detergents. The foam product is passed through ( 26 ) into the thickener ( 22 ). The underflow from the flotation ( 25 ) is passed via ( 27 ) into the spiral classifier ( 28 ) and sprayed with water ( 29 ) there. The suspension containing the sludge is passed into the hydrocyclone ( 32 ) via ( 29 ), pump ( 30 ) and ( 31 ). The underflow is discharged via ( 33 ) as decontaminated soil. The desludged residue discharged by the spiral classifier ( 28 ) is discharged via ( 34 ) as a cleaned bottom. The suspension containing the sludge is passed from the hydrocyclone ( 32 ) via ( 35 ) into the thickener ( 22 ). The dewatered pollutant concentrate is withdrawn from the thickener ( 22 ) via ( 36 ). The water separated in the thickener is passed to waste water purification via ( 37 ).

Embodiments Embodiments 1 to 4

Three different soils contaminated with oil were treated according to the process scheme according to FIG. 1, but without magnetic separation. The drum was 35% filled with steel balls at rest. Diesel oil was added during the flotation. The soils in experiments 1 and 2 came from the same location, but had slight differences in the C content. The figures are% by weight. In experiment 1 the net energy consumption of the drum was 4 kwh / t and in all other experiments 8 kwh / t.

The sieve analyzes of the decontaminated floors were like follows:

The cleaned floors still contain a high level Part of the grain fraction less than 0.063 mm.

Embodiment 5

A soil contaminated with oil was treated according to the process scheme according to FIG. 2. The first drum was filled with stones from the ground to 35% at rest. The net energy consumption of the drum was 2.5 kWh / t. The second drum was 35% filled with steel balls at rest. The net energy consumption of the second drum was 5 kWh / t. During the flotation, emulsified diesel oil was added as a collector.

The screened coarser fraction with a grain size below 6 mm and over 1 mm was used in the second drum.

The table below shows the salary of each Fractions of pollutants indicated in petroleum ether are soluble (PAL).

The raw soil contained 25% with a grain size below 0.06 mm.

When 5% limestone was added to the desludged fraction when fed into the 2nd drum, PAL% in the cleaned soil ( 33 ) was 0.017.

The advantages of the invention are that a large one Part of the contamination in a small part of the soil can be highly enriched and the decontaminated Soils can be used again. This will make the Decontamination of the entire floor is essential more economical and a large part can be reused will. The finest grain fraction under 0.063 mm in the Contaminated soils can be as high as they are high Clay levels pose no difficulty in the Drainage.

Claims (18)

1. Process for the treatment of contaminated soils, which are treated by agitation in an aqueous slurry in a drum with the addition of loose chunks of grinding media with a net energy consumption of 4 to 16 kWh / t throughput, the speed 50 to 90 % of the critical speed of where D is the diameter of the drum in meters, the aqueous slurry discharged from the drum is separated by sieving into a coarser and a finer fraction, the coarser fraction is discharged as a purified fraction, the finer fraction is classified, whereby a coarse fraction accumulates, which is discharged as decontaminated soil, and a suspension from which the solid is removed as a pollutant concentrate after dewatering. 2. Process for the treatment of contaminated soils, which is treated by agitation in an aqueous slurry in a first drum with the addition of loose chunks like grinding media with a net energy consumption of 1 to 6 kWh / t throughput, the speed 50 to 90% of the critical speed of where D is the diameter of the drum in meters, the aqueous slurry discharged from the drum is separated by sieving into a coarser and a finer fraction, the coarser fraction is removed as a purified fraction, from the finer fraction sludge is separated as a suspension, this is dewatered and removed as a pollutant concentrate, the desludged rest of the finer fraction is treated in a second drum with the addition of loose chunks like grinding media with a net energy consumption of 4 to 16 kWh / t throughput, the speed of
50 to 90% of the critical speed of is, sludge is separated from the second aqueous slurry discharged from the second drum, dewatered and discharged as a second pollutant concentrate and the desludged second remainder of the finer fraction is removed as a cleaned soil after dewatering. 3. The method according to claim 1 or 2, characterized in that as the speed 60 to 80% of the critical speed can be used. 4. The method according to any one of claims 1 to 3, characterized in that the Screening takes place at 1 to 2 mm. 5. The method according to claim 3 or 4, characterized in that the desludged remainder of the finer fraction is flotated Foam product is discharged as a pollutant concentrate and the underflow after the drainage is discharged as cleaned soil. 6. The method according to any one of claims 1 to 5, characterized in that as Chunks of steel balls are used and the drum with steel balls up to maximum 40 vol .-%, based on the idle state of the drum.   7. The method according to claim 6, characterized in that in the drum 55 to 65% of the steel balls with a diameter of 20 to 30 mm and 45 to 35% steel balls with a diameter greater than 30 to 100 mm can be used. 8. The method according to any one of claims 1 to 7, characterized in that as Chunks of natural and / or non-natural and / or artificial lumpy material is used and the drum with up to maximum 60 vol .-%, based on the idle state of the drum, with lumpy material is filled. 9. The method according to claim 8, characterized in that lumpy material with a piece size of 60 to 200 mm is used. 10. The method according to claim 8 or 9, characterized in that the drum the discharge side with a grate and discharge blades to regulate the Turbidity is equipped in the drum. 11. The method according to any one of claims 6 to 10, characterized in that as Chunks of steel balls and lumpy material can be used. 12. The method according to any one of claims 1 to 11, characterized in that the Adding the chunks into the drum is controlled so that the energy consumption the drum remains constant. 13. The method according to claim 1, characterized in that the cleaned floor is treated again in a second treatment stage. 14. The method according to claim 13, characterized in that the net Energy consumption of the drum set higher in the second treatment stage is considered in the first stage of treatment.   15. The method according to any one of claims 1 to 14, characterized in that the Sieving the aqueous slurry discharged from the drum into a coarser fraction with a larger grain size, a coarser fraction with a smaller one Grain size and the finer fraction takes place. 16. The method according to any one of claims 1 to 15, characterized in that in the drum feed material with 5 to 40 wt .-% of a grain size smaller 60 µm is used. 17. The method according to claim 16, characterized in that for adjusting the Fine grain content less than 60 µm fine grain minerals are added at least one compound from the group SiO₂, Al₂O₃, CaO and MgO contain. 18. The method according to claim 17, characterized in that the pollutant Concentrate in a rotary kiln by thermal treatment in a dough liquid slag phase is transferred and the composition of the applied benen pollutant concentrate is chosen so that a slag phase is produced, the main components of which make up the basic mass in the area from 60 to 72% SiO₂, 10 to 30% Al₂O₃ and 5 to 25% CaO + MgO, and the main components SiO₂, Al₂O₃, CaO and MgO together at least 60% of the dry and glow loss-free, given to the rotary kiln Contaminant concentrate amount, the discharged slag phase cooled and the exhaust gas from the rotary kiln is subjected to purification. 19. The method according to any one of claims 1 to 18, characterized in that the cleaned soil is mixed with microorganisms.