JP4209224B2 - Method for producing calcium sulfide heavy metal fixing agent - Google Patents

Description

【００３１】

【００３２】
【発明の効果】
本発明は、石膏廃材を原料にして、重金属固定化剤として使用可能な硫化カルシウム系重金属固定化剤を製造する方法を提供するものである。廃棄物の有効利用と重金属による土壌汚染防止の両面から環境負荷の低減に寄与できるため、本発明の効果は極めて大きい。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for producing a calcium sulfide-based heavy metal immobilizing agent that uses gypsum waste and contains calcium sulfide as a main component. More specifically, it can be used to insolubilize heavy metals contained in contaminated soil, drainage, groundwater, municipal waste incineration ash, industrial waste, etc., and it can be added to cement and solidification materials to contain them by solidification. The present invention relates to a method for producing a heavy metal fixing agent mainly composed of calcium sulfide, which functions as a heavy metal fixing agent, by firing gypsum waste.
[0002]
[Prior art]
Gypsum is a hydraulic material that cures in a very short time, has excellent properties such as molding and processability, high dimensional stability, fire resistance and fire resistance, and is an inexpensive material. Although it is widely used as a gypsum board, a prototype or a molding material, the disposal of the waste material has become a big problem as the production amount increases. For example, gypsum board, which is a typical gypsum product, is discharged about 1 million tons per year due to building demolition work and the like. However, since gypsum board waste is used as an interior material for buildings, plasterboard materials (such as plaster plaster, earthen finish, sand wall finish), surface decorative materials such as wallpaper and paint are used on the surface. Many of them are also attached to the base material made of wood or steel, and since it is technically difficult to remove and separate these impurities, most of them are not used effectively. In addition, although landfill processing has been carried out, development of a method for changing to landfill is inevitable due to a decrease in landfillable disposal sites.
[0003]
As a matter of course, various proposals have been made for effective utilization of gypsum board waste. Since gypsum board has a plate-like structure in which a core mainly composed of gypsum is covered with paper, most of the gypsum board is separated from gypsum and paper by crushing or heat treatment, and the admixture contained in gypsum By thermally decomposing, it is used as a raw material for gypsum board or gypsum for cement addition (for example, Patent Documents 1 and 2, Non-Patent Document 1).
However, these methods are merely effective utilization methods only for recovering the original gypsum from the gypsum board waste. While virgin gypsum is available at low cost, waste gypsum is not concentrated in the presence of contaminants and the locations where it is generated, which increases the capital investment and running costs required for the recovery process, resulting in an economical aspect. Therefore, it is currently impossible to beat virgin materials.
Therefore, the development of a practical effective utilization method that changed the viewpoint has become an urgent task.
[0004]
On the other hand, dealing with contaminated soil such as heavy metals is one of the major problems of modern society. One of the permanent countermeasures is solidification containment with cement or solidification material, but this method is based on physicochemical solidification of the soil, and the effect is the properties of the soil (particle size, water content, organic matter content). As a result, there was a limit to immobilization of heavy metals. Further, depending on the soil quality, there has been a problem that hexavalent chromium derived from cement is eluted exceeding the soil environmental standards.
Addition of various reducing agents is known as a measure to suppress elution of hexavalent chromium from solidified soil with cement-based solidifying material. As the reducing agent, ferrous sulfate, sulfite, thiosulfate, sulfur, sulfide, blast furnace slag, hydride (hydrogen sulfide), metal powder (Na, K, Mg, Fe, Zn), etc. are used. . However, there are problems with the sustainability of the medium- and long-term reduction action in the solidified soil, the difficulty in ensuring uniform mixing of the cementitious solidifier and the reducing agent, and the decrease in strength development of the solidified soil. there were.
[0005]
In addition to the reducing agent described above, the heavy metal immobilizing agent by the inorganic substance is roughly classified into an oxidizing agent and a precipitating agent depending on the type of heavy metal to be processed. Oxidizing agents are added for the purpose of pretreatment of COD and BOD reduction in contaminated soil and wastewater, decolorization, iron removal, manganese removal, cyanide and organic mercury oxidation, and heavy metal precipitation. Metal oxides / peroxides, chlorates, halides, etc. are used.
[0006]
On the other hand, a precipitant is added for the purpose of precipitating toxic heavy metals such as cadmium, lead, arsenic, mercury, etc. as sparingly soluble sulfides, calcium salts, hydroxides, sulfides, alkalis, limes. Etc. are used.
However, immobilization of soluble heavy metals in contaminated soil, sludge, drainage, groundwater, municipal waste incineration ash, and industrial waste fails to clear the permissible concentration limit of the target heavy metal, or a complex in which multiple heavy metal species coexist. In the case of contamination, performance degradation may occur, and the performance of the above-described conventionally used reducing agents and precipitants is naturally limited.
[0007]
The present inventor has found that among these, calcium sulfide exhibits an excellent effect as a hexavalent chromium elution inhibitor and a heavy metal insolubilizing agent from the solidified soil.
However, calcium sulfide is currently only a high-purity reagent on the market, is expensive, difficult to be applied to the above-mentioned uses, and development of a practical manufacturing method has been desired. Is.
[0008]
[Patent Document 1]
JP-A-6-142638 (2 pages)
[Patent Document 2]
JP 10-36149 A (2 pages)
[Non-Patent Document 1]
Ministry of the Environment, “Survey on Recycling Waste Gypsum Board (December 2002)” (page 23)
[0009]
[Problems to be solved by the invention]
The purpose of the present invention is to use gypsum waste materials whose emissions are increasing year by year and for which development of effective utilization methods is desired as raw materials, contaminated soil, drainage, groundwater, municipal waste incineration ash, heavy metals in industrial waste It is in providing the practical manufacturing method of the calcium sulfide type | system | group heavy metal fixing agent which was excellent in the detoxification performance.
[0010]
[Means for Solving the Problems]
Inventor includes the steps of obtaining a step of milling the gypsum board waste material not separated paper, mixing the mixture of gypsum board waste material not separated was pulverized paper and the waste timber, the mixture in a reducing atmosphere 600 Excellent heavy metal immobilization performance by including a step of obtaining a calcined product containing 22.6 to 76.43% by mass of calcium sulfide by heat treatment at 1100 ° C and a step of obtaining a heavy metal fixing agent by crushing the calcined product. The present inventors have found that a calcium sulfide-based fixing agent possessed can be produced.
That is, the present invention includes the steps of grinding the gypsum board waste material not separated paper, and a step of obtaining a mixture the mixture of gypsum board waste material not separated was pulverized paper and the waste timber, the mixture in a reducing atmosphere A heavy metal comprising a step of obtaining a fired product containing 22.6 to 76.43% by mass of calcium sulfide by heat treatment at 600 to 1100 ° C., and a step of obtaining a heavy metal fixing agent by pulverizing the fired product. The present invention relates to a method for producing a calcium sulfide-based fixing agent for use as a fixing agent.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
The present invention is described in detail below.
Gypsum waste in the present invention, the gypsum board can be used. Of these, about 7% by mass of paper is currently attached to the gypsum board that is discharged most in quantity as gypsum waste. However, in the present invention in which gypsum waste is fired in a reducing atmosphere, the paper is separated. It does not need to be performed and functions effectively as a part of the reducing agent added to the gypsum waste material.
Further, the gypsum waste material used in the present invention is used after being pulverized, but it is desirable to pulverize it to 5 mm or less in order to promote the reduction reaction of gypsum efficiently. The pulverization method is not particularly limited.
[0012]
After the pulverization process, large metals are removed using a magnetic separator and a sieve, but small metals may remain.
[0013]
It means for firing pulverized gypsum waste in a reducing atmosphere, you firing a mixture of waste wood as a reducing agent to gypsum waste.
[0014]
The addition amount of the reducing agent to the gypsum waste is preferably added calculated by reducing equivalent value or more reducing agents. Besides carbon generated turned into coal, hydrocarbons, H2, reduction by carbonization gas such as CO even in consideration to calculate the reduction equivalent, it is preferable to present its value or more reducing agents.
[0015]
In the present invention, it is not always necessary that all gypsum is converted to calcium sulfide, but it is preferable that 20% by mass or more of all gypsum is converted to calcium sulfide.
[0016]
The temperature for firing the pulverized gypsum waste material is set to 600 to 1100 ° C. If the calcination temperature is lower than 600 ° C, it takes too much time to reduce the gypsum, which is not preferable because the production efficiency is lowered. On the other hand, when the temperature is higher than 1100 ° C., the generated calcium sulfide is severely decomposed and not only the yield is lowered, but also environmental measures are required due to generation of SOx gas.
[0017]
The heating furnace for firing the waste gypsum is not particularly limited as long as it can be heated to a predetermined temperature, such as an internal combustion burner type rotary kiln, an external heating type rotary kiln, a double cylinder rotary kiln type carbonization furnace, a batch type carbonization furnace or the like.
In addition, when using a heating furnace such as an internal combustion burner type rotary kiln that is used for firing cement and lightweight aggregates, the inside cannot be completely reduced in terms of structure. Since the fired product comes into contact with the atmosphere having a high temperature and a high oxygen concentration over the kiln opening, the decomposition of calcium sulfide is likely to occur. In order to minimize the decomposition of calcium sulfide, it is desirable to granulate the raw material in advance to about 10 to 30 mm and to fire it.
[0018]
As a granulation method used for this granulation, for example, any method such as extrusion granulation, briquette granulation, stirring granulation and the like may be used, and there is no particular limitation.
If a firing furnace having a structure capable of maintaining the inside in a reducing atmosphere, such as a carbonization furnace, is used, this granulation step can be omitted.
[0019]
The obtained fired product can be pulverized by a known method such as a ball mill, vertical roller mill, vibration mill, pin mill, etc., to obtain a calcium sulfide heavy metal fixing agent. In addition, since it uses as a heavy metal fixing agent use, it is preferable to grind | pulverize to an average particle diameter of 100 micrometers or less.
[0020]
If the obtained calcium sulfide-based heavy metal immobilizing agent is simply used for immobilizing heavy metals, only the powder is added to the object to be treated, but it is necessary to solidify the object to be treated. For example, it is used in combination with cement or a solidifying material.
[0021]
【Example】
Hereinafter, the present invention will be described in more detail with reference to specific examples.
Gypsum board waste material (9.5 mm thick gypsum board, about 94 mass% of gypsum, about 6 mass% of paper) collected from the building demolition work site, using a jaw crusher and an atomizer, all the 3 mm sieves with paper It grind | pulverized to the particle size to pass. Waste wood recovered from the construction site is first crushed with a chipper shredder, and then pulverized to a particle size that passes through a 3 mm sieve using a vertical roller mill. 6: 4 was mixed. Furthermore, 20 g of the mixture was put into a ship-shaped crucible, and heated at 500 ° C. to 1200 ° C. for 4 hours while flowing nitrogen gas at 0.5 L / min in a gas flow type tubular electric furnace (diameter 60 mm × height 1000 mm). The SOx concentration in the gas generated during firing was measured using a gas detector tube.
[0022]
The obtained fired product was measured for sulfur and sulfur trioxide content in sulfide form according to JIS R5202. The amount of calcium sulfide and the amount of calcium sulfate were calculated from the following equations, and the reaction rate from gypsum to calcium sulfide was determined.
Calcium sulfide amount = sulfide form sulfur amount × (72.14 / 32.06)
Calcium sulfate amount = sulfur trioxide amount × (136.14 / 80.06)
Reaction rate = (calcium sulfide amount / 72.14) / ((calcium sulfide amount / 72.14) + (calcium sulfate amount / 136.14))
[0023]
Furthermore, the obtained fired product was pulverized to an average particle size of 10 μm using a ball mill, and used in combination with a cement-based solidified material or used alone to confirm the effect of immobilizing heavy metals. In addition, when using a solidifying material together, a general soft soil cement-based solidifying material was used.
The properties of the fired product are shown in Table 1.
[0024]
Evaluation of the effect of immobilizing heavy metals in the fired product was performed as follows.
The following three kinds of heavy metal immobilization treatment objects were selected.
(I) Volcanic ash cohesive soil (natural water content ratio 104.6%) Non-contaminated soil (b) Sandy soil (natural water content ratio 18.5%) Hexavalent chromium contaminated soil: Hexavalent chromium according to Notification 46 of the Environment Agency Elution amount: 1.02 mg / L
(C) Municipal waste incineration ash Complex pollutants: Dissolution amount in the dissolution test by the Environmental Agency Notification No. 13 before humidity control: Cadmium 20.1 mg / L, Arsenic 0.26 mg / L, Lead 0.81 mg / L, hexavalent chromium 0.98mg / L
The municipal waste incineration ash was conditioned by spraying water and stirring in advance so that the water content was 18% by mass.
[0025]
The heavy metal treatment object was treated with the heavy metal fixing agent and the solidifying material as follows.
That is, a heavy metal fixing agent and a solidifying material were added to the object to be treated, mixed with stirring, filled into a mold (diameter 5 cm × height 10 cm), compacted, and sealed and cured in a temperature-controlled room at 20 ° C. and humidity 60%. . After 7 days, the mold was removed to obtain a specimen.
[0026]
For the specimen after demolding, the following evaluation test was performed.
Compressive strength: uniaxial compressive strength was measured according to JIS A 1216.
・ Elution amount of heavy metal: For non-contaminated soil (volcanic ash clay), the elution amount of hexavalent chromium derived from cement from solidified soil with solidification material was measured by the Environmental Agency Notification No. 46 method. The amount of elution of heavy metals was measured in accordance with Environment Agency Notification No. 46 for contaminated soil and in accordance with Environment Agency Notification No. 13 for municipal waste incineration ash.
The evaluation results are shown in Table 2. Regarding the amount of heavy metal elution, “<(detection limit value)” is described when the heavy metal concentration is below the detection limit.
[0027]
As shown in Table 1, it can be seen that the concentration of sulfur dioxide gas significantly increases at a firing temperature of 1200 ° C.
In Table 2, No. 1-9 are hexavalent chromium elution test results from volcanic ash cohesive soil solidified using calcium sulfide AH obtained by firing at 500-1200 ° C. and a general soft soil cement-based solidifying material. However, when the heavy metal fixing agent A having a firing temperature of 500 ° C. is used, the effect of suppressing the elution of hexavalent chromium from cement or the like is not sufficient because the amount of calcium sulfide produced is small.
[0028]
No. 10-13 are the dissolution test results from the hexavalent chromium-contaminated soil in which heavy metal was fixed using calcium sulfide C obtained by firing at 700 ° C. and a general soft soil cement-based solidifying material, Even when the amount added to the contaminated soil was 1.0 kg / m ³ , the hexavalent chromium elution suppression effect from the contaminated soil was observed.
[0029]
No. 14 to 16 are solute test results when calcium sulfide D obtained by firing at 800 ° C. is added alone to municipal waste incineration ash which is a composite pollutant containing cadmium, arsenic, lead and hexavalent chromium. By adding 2.0 kg / m ³ or more to the object to be treated, complex and sufficient containment with respect to various heavy metals becomes possible.
[0030]
[Table 1]

[0031]

[0032]
【The invention's effect】
The present invention provides a method for producing a calcium sulfide-based heavy metal immobilizing agent that can be used as a heavy metal immobilizing agent using gypsum waste as a raw material. The effect of the present invention is extremely great because it can contribute to the reduction of environmental burden from both the viewpoint of effective use of waste and prevention of soil contamination by heavy metals.

Claims (1)

Crushing gypsum board waste that has not been separated from paper ;
Mixing the waste paper and gypsum board waste material that has not separated the crushed paper to obtain a mixture;
Heat-treating the mixture at 600 to 1100 ° C. in a reducing atmosphere to obtain a fired product containing 22.6 to 76.43% by mass of calcium sulfide;
Crushing the fired product to obtain a heavy metal fixing agent;
A method for producing a calcium sulfide-based heavy metal immobilizing agent, comprising: