JP2003181438A - Method for decontaminating contaminated soil - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for decontaminating contaminated soil by which cyan ions (CN-) can be selectively separated as gaseous hydrogen cyanide (HCN) from the soil contaminated with cyan and further the cyan ions (CN-) separated from the contaminated soil can be recovered by properly controlling heating conditions. <P>SOLUTION: In the method for decontaminating contaminated soil containing cyan compounds, the cyan compounds are separated from the soil as the gaseous hydrogen cyanide by indirectly heating the contaminated soil in an atmosphere of thin oxygen. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for purifying contaminated soil for separating cyanide compounds from cyanide-contaminated soil,
In particular, it is possible to effectively generate hydrogen cyanide gas by heating the cyanide compound in the soil under appropriate conditions, collect the generated hydrogen cyanide gas, and recover reusable clean soil from the contaminated soil. The present invention relates to a method for cleaning contaminated soil.

[0002]

2. Description of the Related Art The number of cases in which soil pollution at a former factory site is found in soil investigations accompanying redevelopment of urban areas and changes in land use is increasing. In this case, as a measure against soil contaminated with heavy metals including cyanide compounds, generally, cement or the like is added to the contaminated soil to solidify or insolubilize it, and then contain it in a facility where water-blocking work or blocking work is performed. , The method of shielding from the surrounding environment is adopted.

[0003]

On the other hand, a technique for separating and removing pollutants from soil is being developed, and a heat treatment method is one of them. However, for example, a report issued by the United States Environmental Protection Agency (US EPA) (eg, EPA 542-B-97-
In 008), it is judged that "the heat treatment method cannot be expected to be effective on inorganic cyanide compounds as the applicability of heat treatment to cyanide-contaminated soil". As the background, as one index of applicability of the heat treatment method,
There is a boiling point of the target pollutant, and the boiling point of the inorganic cyanide compound is generally very high.

On the other hand, for example, Japanese Patent Laid-Open No. 2000-2
Japanese Patent Laid-Open No. 63031 proposes a method of treating a cyan compound by hydrolysis, but the possibility that the CN bond of the cyan ion (CN-) is hydrolyzed is extremely low. Further, the cyan compound can oxidize and decompose the cyan ion (CN-) in the cyan compound into carbon dioxide (CO ₂ ) and nitrogen (N ₂ ) by burning it at 600 to 900 ° C or higher. Since the treatment facility corresponds to the incineration facility, it is legally treated as an intermediate treatment of industrial waste, and it is practically impossible to treat by this method.

In view of the problems of the conventional methods for purifying contaminated soil, the present invention selects cyanide ion (CN-) as hydrogen cyanide gas (HCN) from cyanide contaminated soil by appropriately controlling heating conditions. Cyanide (CN-) separated from contaminated soil
It is an object of the present invention to provide a method for purifying contaminated soil capable of recovering.

[0006]

In order to achieve the above object, a method for purifying contaminated soil according to the present invention is a method for purifying contaminated soil containing a cyanide compound. It is characterized in that the cyan compound is separated from the soil as hydrogen cyanide gas by indirectly heating below.

[0007] In this method for cleaning contaminated soil, the contaminated soil is indirectly heated in an oxygen-diluted atmosphere to cause a cyanide compound to react with moisture and carbon dioxide in the soil, thereby converting cyanide ions from the contaminated soil into hydrogen cyanide gas. It can be separated and removed, which makes it possible to purify contaminated soil and reuse it as clean soil.

In this case, the separated hydrogen cyanide gas can be collected and recovered by the generated gas recovery device.

As a result, the separated hydrogen cyanide gas can be recovered, the recovery process can be simplified, the initial cost of the processing equipment can be reduced, and the atmospheric environment can be prevented from being polluted.

Further, the heating temperature of the indirect heating is 300 to
It can be 650 ° C.

As a result, the cyanide compound can be selectively separated from the contaminated soil.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the method for purifying contaminated soil according to the present invention will be described below based on specific experimental examples.

This purification method for contaminated soil is performed by indirectly heating contaminated soil in an inert gas atmosphere in which oxygen is diluted when purifying soil contaminated with a cyanide compound.
Hydrogen cyanide gas is generated, and cyan compounds are separated and removed from soil as hydrogen cyanide gas. The contaminated soil is heated by an indirect heating device (not shown). By appropriately introducing the contaminated soil and discharging the treated soil, the inflow of air into the heating device is suppressed as much as possible and oxygen is diluted. Try to maintain the condition. As a result, it becomes possible to suppress the ignition of organic substances contained in the soil and selectively remove pollutants. The heating temperature is 3 depending on the target soil
The heating time can be appropriately adjusted within the range of 00 ° C to 650 ° C, and the heating time can be appropriately adjusted within the range of 5 minutes to 1 hour.

The cyanide compound has a property of generating hydrogen cyanide gas upon contact with acid or carbon dioxide gas in the presence of moisture.
In the present invention, by utilizing this property, the cyanide compound contained in the soil is reacted with water and carbon dioxide in the soil to be converted into hydrogen cyanide gas, which is then separated and removed. In this case, carbon dioxide is decomposed by thermal decomposition of carbonate contained in soil interstitial air or soil (for example, CaCO ₃ → C).
aO + CO ₂ ). Cyan compound (M-
CN) reacts in the heating device as in the following formula (1),
Change to hydrogen cyanide gas (HCN). 2M-CN + CO ₂ + H ₂ O → M ₂ CO ₃ + 2HCN (1)

The generated hydrogen cyanide gas is guided to the outside of the heating device together with the heated and expanded soil gas and introduced into the generated gas recovery device. This generated gas recovery device
For example, an alkaline aqueous solution such as an aqueous sodium hydroxide solution is used as an absorbing liquid, and hydrogen cyanide gas is dissolved in the absorbing liquid to recover the hydrogen cyanide gas. By collecting and recovering hydrogen cyanide gas with this generated gas recovery device, it is possible to simplify the processing equipment for the separated and removed pollutants. The soil to be purified in the present invention contains a cyanide compound or a cyanide compound and oils, and the cyanide compound and oils can be separated and removed at the same time.

[0016]

EXAMPLES Next, examples of the present invention will be described in more detail. Table 1 below shows the content and other properties of the 6 types of pollutant components that are the targets of the method for cleaning polluted soil of the present invention. A to E are simulated contaminated soils prepared by mixing clean soil with a cyanide compound, and F is an actual contaminated soil actually contaminated with a cyanide compound. A was prepared by mixing potassium cyanide, which is a typical cyanide substance, and silica sand No. 5, and B was prepared by mixing potassium ferrocyanide trihydrate, which is a ferrocyanide complex, and silica sand No. 5. C to E are potassium ferricyanide (ferri-ferro type), which is a typical chemical form of iron cyano complex, so-called Prussian blue, and silica sand 5
No., Masa soil, and loam. For clean sand, use silica sand after drying it in an oven to dry it.
The masa soil and loam were air-dried and then mixed with a cyanide compound to prepare a simulated contaminated soil. The analysis method and evaluation method for cyanide in soil are described in JIS K0102 38.
Performed according to 1.2 and 38.2. The same applies to the analysis method and evaluation method of cyanide in the soil after the purification treatment. Further, the dissolution test was carried out according to the 1991 Environmental Agency Notification No. 46.

[0017]

[Table 1]

On the other hand, as the heat treatment method for the test soil, electric furnace heating and tubular furnace heating were appropriately used. The test procedure for each heat treatment method is as follows. (1) Electric furnace heating: Take an appropriate amount of sample in an evaporation dish and set it in the electric furnace. Nitrogen gas was purged as an inert gas into the furnace in order to create a state in which the amount of air inflow was small and oxygen was lean. Then, heating was performed under each heating condition, and the cyan content of the heat-treated soil was measured. (2) Tubular furnace heating: In order to confirm the material balance during the heat treatment of cyanide-contaminated soil, heat treatment was performed using a tubular furnace. Nitrogen gas was injected into the quartz tube as a carrier gas in order to collect gas generated during heating. The gas passing through the quartz tube was cooled by a cooling tube and then collected by an impinger. A 0.5 M NaOH solution was used as the absorbing solution. First, an appropriate amount of sample is taken in the quartz port and inserted into the quartz tube. After the insertion, a carrier gas was flowed until the inside of the tube was sufficiently replaced, and then heat treatment was performed at 500 ° C. Then, after heating, the cyan content of the treated soil and the cyan concentration in the absorbing solution were measured.

(Example 1) Table 2 below shows the results of heat treatment of simulated polluted soil in an electric furnace. From this result, under the condition that the heating time was 5 minutes, most of the iron cyano complex was removed by heating at 500 ° C. or higher regardless of the difference in soil quality.
In the case of cyanide, which is easily liberated, when heat treatment was performed at 500 ° C. for 5 minutes, the removal amount increased due to the presence of water.

[0020]

[Table 2]

Example 2 Next, Table 3 below shows the results of heating the simulated contaminated soils A to E in a tubular furnace. In the case of the cyanide of the test soil A, the residual rate is high under the conditions of heating temperature of 500 ° C. and heating time of 5 minutes, and the heating time needs to be relatively long, but when water is present, the removal amount also increases. However, hydrogen cyanide is generated. In the case of the test soil B, the residual amount is relatively large, but by removing the heating time for a long time, most of the removed cyanide was collected as hydrogen cyanide. For the test soils C to E, the heating temperature is 5 regardless of the soil type.
Under the conditions of 00 ° C., heating time of 5 minutes, and nitrogen gas purging, most of cyan was removed, and the amount of hydrogen cyanide recovered was high. From these results, it was found that most of the iron cyano complex in the cyanide-contaminated soil is removed as hydrogen cyanide by indirect thermal desorption in which heat treatment is performed in the absence of oxygen. In the case of other cyanides, a small amount of hydrogen cyanide is generated due to the presence of water.

[0022]

[Table 3]

(Example 3) Next, based on the results of Examples 1 and 2, the test soil F (actually contaminated soil) was heat-treated by electric furnace heating and tubular furnace heating. The results are shown in Table 4 below. In the electric furnace heating, the cyanide in the soil is sufficiently treated when the heating temperature is 400 ° C. or higher and the heating time is 5 minutes, and the elution amount is not detected when the heating time is 10 minutes. Even when the heating temperature was 300 ° C., the cyan content was sufficiently reduced after heating for 20 minutes. Further, when heat-treated in a tubular furnace under conditions of a heating temperature of 500 ° C., a heating time of 5 minutes, and a nitrogen gas purge, the cyanide compound in the treated soil was sufficiently treated, and the elution amount was below the detection limit value, and the treated cyanide was treated. Most of the compound was recovered as hydrogen cyanide. As a result, when cyanide-contaminated soil is subjected to indirect thermal desorption treatment in a state where air inflow is small and oxygen is diluted, most of the cyanide compounds in the soil are removed by heating for 5 minutes or more, and cyanide compounds are separated as hydrogen cyanide. I was able to recover it.

[0024]

[Table 4]

[0025]

According to the method for cleaning polluted soil of the present invention,
By indirectly heating the contaminated soil in an atmosphere with a low oxygen content, the cyanide compound can react with the moisture and carbon dioxide in the soil to separate and remove cyanide ions from the contaminated soil as hydrogen cyanide gas. It becomes possible to purify the soil and reuse it as clean soil.
Then, according to this method for purifying contaminated soil, among cyan compounds often present in contaminated soil, in particular, since it is possible to reliably and efficiently separate and remove the iron cyano complex, extremely. It can be said that it is a highly effective method for purifying contaminated soil.

Further, the separated hydrogen cyanide gas can be recovered by collecting and recovering the separated hydrogen cyanide gas by the generated gas recovery device, and the recovery process can be simplified and the initial cost of the processing equipment can be reduced. It is possible to prevent pollution of the atmospheric environment.

Further, the heating temperature of the indirect heating is set to 300.
By setting the temperature to 650 ° C, the cyanide compound can be selectively separated from the contaminated soil.

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Takuo Nakajima             3-2-23 Minoh, Minoh City, Osaka Prefecture             -Avenue 207 F-term (reference) 4D004 AA41 AB05 CA22 CA37 DA03                       DA08

Claims (3)

[Claims] 1. A method for purifying a contaminated soil for purifying a contaminated soil containing a cyanide compound, wherein the contaminated soil is indirectly heated in a dilute oxygen atmosphere to separate the cyanide compound from the soil as hydrogen cyanide gas. Method for cleaning contaminated soil. 2. The method for purifying contaminated soil according to claim 1, wherein the separated hydrogen cyanide gas is collected and collected by a generated gas recovery device. 3. The heating temperature of the indirect heating is 300 to 65.
The method for purifying contaminated soil according to claim 1 or 2, wherein the temperature is 0 ° C.