JP4596737B2 - Soil restoration material comprising ferrihydrite humus complex and method for producing the same - Google Patents

Description

[0001]
【Technical field】
  The present invention relates to a ferrihydrite humus complex.Soil restoration material consisting ofIn particular, ferrihydrite humus composites made from organic waste that can be processed simultaneously with organic wasteSoil restoration material consisting ofIt is about.
[0002]
[Background]
  In recent years, environmental pollution on the earth has become serious, and interest in environmental problems has increased. As one of the environmental pollutions, secondary pollution due to methane gas generated from organic matter in waste such as domestic waste, industrial waste, and industrial wastewater sludge that is disposed of in landfills has become a problem. In addition, pollution such as increase in BOD of lakes, rivers, etc. due to the influence of organic matter flowing out from waste has become a problem, and active research is being conducted on measures to prevent such pollution.
[0003]
  And by recent research, goethite (Goethite; goethite; α-FeOOH), ferrihydrite (Ferrihydrite; amorphous iron hydrated oxide: 5FeO)₂O₃・ NH₂Secondary iron oxides such as O) have the property of coordinating with the OH end and O end of the carboxyl group and carbonyl group of an organic compound, and form an aggregate to precipitate, and thus contain organic matter. It has been found effective for the physical clarification of the suspension. In particular, among these secondary iron oxides, ferrihydrite has a large specific surface area and a large ability as a catalyst to provide a field for chemical reaction, so that the oxidation of the organic substance of amorphous iron hydrated oxide is performed. It has been found to be particularly effective in promoting polymerization and decomposition of nitrogen oxides, and effective in pollution caused by organic waste.
[0004]
  However, ferrihydrite is only collected from nature, and a method for producing ferrihydrite is not known. Development of a method for producing ferrihydrite capable of adsorbing and decomposing and deactivating organic compounds is desired.
  On the other hand, organic waste that causes environmental pollution is currently being landfilled. Elution of refractory substances such as cadmium, mercury, dioxins, DDT (dichlorodiphenyltrichloroethane), PCB (polychlorinated biphenyl) from organic waste, BOD of rivers near waste disposal sites where organic waste is discarded, The rise in COD has become a problem, and the development of an efficient and reliable method for treating organic waste is desired.
[0005]
  SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems, and is capable of decomposing and decomposing organic compounds and inactivating ferrihydrite.Soil restoration material consisting of humus complexFerrihydrite for industrial productionOf soil restoration material consisting of humus complexIt is to provide a manufacturing method.
  Another object of the present invention is ferrihydrite capable of simultaneously treating organic waste in the production process.Of soil restoration material consisting of humus complexIt is to provide a manufacturing method.
[0006]
DISCLOSURE OF THE INVENTION
  The method for producing a soil restoration material comprising a ferrihydrite humus complex according to the present invention includes a pH adjusting step for adjusting the pH of an organic substance to 5 or more, and maintaining the pH of the organic substance to 5 or more while introducing oxygen. However, the organic substance contains the most iron in the metal, and the iron is in the liquid., PAt a pH higher than H5, Fe (OH)₃Mineral liquid obtained by extracting with mineral acid at least one sedimentary rock soil that consists of basalt and andesiteTheAdjust to pH 5-7Mineral water solutionAnd a mineral aqueous solution immersing step for immersing, and maintaining the pH of the organic substance at 5 or more and stirring the organic substance, the fermentation aid and the mineral liquid are added to the organic substance.Mineral liquid diluted with waterA primary fermentation step of spraying a mixed solution of an aqueous solution, while maintaining the pH of the organic matter at 5 or higher and depositing the organic matter in a compost and fermenting, while turning back when the organic matter reaches a predetermined temperature Said mineral liquidMineral liquid diluted with waterIt is characterized by comprising a secondary fermentation / ripe process for spraying an aqueous solution to obtain a fully fermented compost.
[0007]
  as mentioned above,organic matterAdd mineral liquid aqueous solution toRutaFe (OH) contained in mineral liquid₃Whenorganic matterAnd ferrihydrite that can be used as a soil recovery materialHumus complexCan be formed.
  Primary fermentation process and secondary fermentation / ripening processAt the same time as the addition of the mineral aqueous solution,organic matterTherefore, ferrihydrite humus composites having performance as general compost as well as performance as soil recovery material peculiar to ferrihydrite can be produced.
  In this manufacturing method,organic matterTo use as a raw material,organic matterIf organic waste is used, not only ferrihydrite production but also organic waste treatment by composting can be performed at the same time.
  Furthermore, since the mineral liquid according to the present invention contains the collected mineral, this mineral acts as a coenzyme, and high microbial activity is obtained.Primary fermentation process, secondary fermentation / ripe processEfficient fermentation is carried out.
[0008]
  Moreover, since the pH adjustment process is performed, in the later mineral liquid aqueous solution immersion process, primary fermentation process, secondary fermentation / ripening process, iron contained in the mineral liquid aqueous solution is used as a ferrihydrite raw material (Fe ( OH)₃Thus, ferrihydrite can be formed.
  Also, mineral liquidAqueous solutionSince the pH of the organic substance is adjusted to 5 or more in the pH adjustment step before the dipping step, it becomes possible to set the pH of the mineral solution aqueous solution to 5 or more in the mineral solution aqueous solution dipping step. In addition, Fe (OH) as a raw material for ferrihydrite₃(Iron hydroxide) can be present. As a result, it is possible to prevent the organic substance from forming a complex with other elements such as aluminum and magnesium. The humus complex can contain iron that has a very low possibility of adversely affecting living organisms and ecosystems. Furthermore, it is possible to form a humus complex containing ferrihydrite which has a large surface area where the reaction occurs and a large physicochemical reaction force due to the mutation charge characteristic caused by pH change.
[0009]
  In addition, primary fermentation process, secondary fermentation, ripe processBefore performing the mineral aqueous solution immersion process,organic matterMore mineral liquid aqueous solution can be contacted and more ferrihydrite can be formed.
  Under anaerobic conditions, trivalent iron becomes divalent iron. However, in the present invention, since the mineral liquid aqueous solution immersion step is performed while oxygen is supplied in this way, in the mineral liquid aqueous solution immersion step, trivalent iron is 2 It becomes possible to prevent becoming a valence iron.
Moreover, since the pH of the mineral liquid aqueous solution is set to 5 to 7 in the mineral liquid aqueous solution immersion process, composting in the subsequent primary fermentation (mineral liquid addition) process 4 and secondary fermentation / ripening (mineral liquid addition) process 5 It is possible to prevent the bacteria that ferment in the process from being killed.
[0010]
Iron is a mineral liquid, and at pH 3 or less, Fe ³⁺ At pH 3 to pH 4, Fe ³⁺ And Fe (OH) ₂ ⁺ At pH 4 to pH 5, Fe ³⁺ And Fe (OH) ²⁺ And Fe (OH) ₂ ⁺ At pH higher than pH 5, Fe (OH) ²⁺ And Fe (OH) ₂ ⁺ And Fe (OH) ₃ Fe (OH) that exists as a raw material for ferrihydrite at pH 5 or higher ₃ Therefore, it becomes possible to manufacture the soil recovery material which consists of ferrihydrite humus composites using this mineral liquid.
[0011]
  The iron contained in the mineral liquid is Fe (OH) at pH 5 or higher. ₃ Therefore, in order to form ferrihydrite, it is necessary to keep the pH of the mixture of the mineral liquid aqueous solution and the organic matter at 5 or more, but in the primary fermentation step and the secondary fermentation / ripening step, the pH of the organic matter is adjusted. Since it is maintained at 5 or more, it becomes possible to form ferrihydrite..
  In the secondary fermentation / ripening process, the organic matter is turned over when the temperature reaches a predetermined temperature, so that sufficient oxygen can be supplied to prevent the reduction of trivalent iron necessary for ferrihydrite formation. Can do.
[0012]
The predetermined temperature is preferably 65 ° C. or higher.
Thereby, it becomes possible to obtain fully fermented compost from organic matter.
[0013]
  Also,After the secondary fermentation / ripening step, a mineral addition step after composting is carried out at 40 to 50 ° C. while sprinkling the aqueous solution of mineral liquid while stirring the fully matured fertilizing compost and adjusting the water content of the fully fermented fertilizing compost.It is preferable.
  Since it comprises in this way, the water | moisture content of a fully-ripened fermented compost can be evaporated, it can be made into a suitable water content as compost | cure, and it can prevent that the various components contained in a fully-ripened fermented compost | leaching are leached.
[0014]
  In the pH adjustment step, it is preferable to adjust the pH of the organic substance to 7 or more.
Fe (OH), which is a raw material for the production of ferrihydrite when the pH of the mineral liquid is gradually increased from a low pH ₃ Is started at pH 5 and reaches a substantially maximum amount at pH 7.
In addition, it is preferable to perform C / N adjustment of the organic matter before the pH adjustment step.
[0015]
  Also,The primary fermentation process and the secondary fermentation / ripe process are:It is preferable to carry out the process while maintaining the iron in the mineral liquid in a trivalent state.
  Because of this structure, iron becomes divalentorganic matterIt is possible to prevent leaching from a mixture of mineral liquid.
[0016]
in frontIt is preferable that the sum of the amount of magnesium and the amount of calcium contained in the mineral liquid is less than 30% by weight of the amount of iron contained in the mineral liquid.
  Fe (OH) with a high content of magnesium or calcium₃This is because ferrihydrite is not formed because the formation of is inhibited.
[0017]
  AbovepH adjustment processBefore the inorganic acid extraction step of extracting at least one sedimentary rock soil composed of basalt and andesite with an inorganic acid to prepare the mineral liquid. In the inorganic acid extraction step, pure iron (Fe (3+ )) And amorphous goethite (α-FeOOH) and the mineral liquid are preferably obtained.
  The mineral liquid from which such residues are separated is the ferrihydrite raw material Fe (OH).₃Fe to be the basis of³⁺As a result, ferrihydrite can be formed.
[0018]
  Furthermore, the soil restoration material consisting of the ferrihydrite humus complex of the present invention,Manufactured by the manufacturing method of claim 1,A soil recovery material consisting of a ferrihydrite humus complex and a fully mature organic compost formed by fermenting organic matter in the presence of an aqueous solution of an inorganic acid extract of sedimentary rock soil of pH 5-7, The inorganic acid extract contains the most iron in the metal and contains the iron., PAt a pH higher than H5, Fe (OH)₃It is characterized by including as.
  By comprising in this way, it becomes possible to obtain the ferrihydrite humus complex which has the performance as general compost in addition to the performance as a soil recovery material peculiar to ferrihydrite. Ferrihydrite has a specific surface area of about 200 (m²/ G) and a large field for reaction with the OH end and O end of the organic compound, so that it is possible to obtain a soil recovery material with high catalytic ability and ability to form aggregates. Become.
  Moreover, since this ferrihydrite humus complex contains the mineral derived from an inorganic acid extract, it becomes possible to obtain a soil recovery material capable of promoting the activity of microorganisms and enzymes and improving the environment of microorganisms.
  In addition, ferrihydrite has the property of detoxifying and precipitating bio-concentrated harmful substances, so it is possible to obtain soil recovery materials that can fix and inactivate persistent substances contained in organic waste. It becomes.
[0019]
  In addition, it is suitable that the sum of the amount of magnesium and calcium contained in the inorganic acid extract is less than 30% by weight of the amount of iron contained in the inorganic acid extract.
  Thus, Fe (OH)₃Since the amount of magnesium and calcium that inhibit the formation of humus is small, a humus complex containing a large amount of ferrihydrite can be obtained.
[0020]
Moreover, it is suitable that the water content is 10 to 20% by weight.
Since it is configured in this way, the soil recovery material composed of the ferrihydrite humus complex can be made into an appropriate amount of water as compost, the amount of water in the organic compost is too much, and various kinds of organic compost contained in the compost Can be prevented from leaching.
[0021]
BEST MODE FOR CARRYING OUT THE INVENTION
  Embodiments of the present invention will be described below with reference to the drawings. Note that the members, arrangements, and the like described below do not limit the present invention and can be variously modified within the scope of the gist of the present invention.
(Embodiment 1)
  In the present embodiment, a ferrihydrite humus complex that is artificially a kind of iron hydrated oxide is produced through the manufacturing process of compost (coarse humus) of this organic material using a mineral aqueous solution and an organic material as raw materials.Soil restoration material consisting ofIt is a method of manufacturing.
  Here, in this specification, the ferrihydrite humus complex refers to a complex of amorphous ferrihydrite (hereinafter referred to as ferrihydrite) and an organic substance. Moreover, "humus" means soil organic matter in this specification, and is synonymous with compost.
  Ferrihydrite is a general formula of 5FeO₂O₃・ 9H₂It is an amorphous hydrated oxide represented by O. Generally, it is known as a low-crystallinity iron mineral formed at an early stage in the earth's surface layer.
  Ferrihydrite has the property of coordinating with the OH end and O end of a carboxyl group or carbonyl group of an organic compound, and forms an aggregate. Specific surface area is about 200 (m²/ G), and a wide field for reaction with the OH end and O end of the organic compound, it is known that the catalytic ability is high and the ability to form aggregates is high.
[0022]
  In the present embodiment, a natural ionized mineral concentrate extracted by adding an inorganic acid to sedimentary rock soil such as basalt and andesite is used as the mineral liquid. In the present specification, this ionized mineral concentrate is referred to as a mineral liquid. Examples of the mineral liquid include Clay Extract W. manufactured by Lion Corporation. Use W.
  The mineral liquid is an acid-soluble component extracted by adding an aqueous sulfuric acid solution having a concentration of 10 to 20% by weight to sedimentary rock soil (clay) such as basalt and andesite. Instead of sulfuric acid, hydrochloric acid, nitric acid, a mixture of these inorganic acids, or an aqueous solution thereof may be used. However, when a sulfuric acid aqueous solution having a concentration of 10 to 20% by weight is used, the following embodiment will be described. A mineral liquid can be obtained efficiently.
[0023]
  The mineral liquid of the present embodiment contains iron (Fe) as a main component, and also contains cations such as manganese (Mn), magnesium (Mg), and calcium (Ca). However, the sum of the amount of magnesium and the amount of calcium is less than 30% by weight of the amount of iron contained in the mineral liquid.
  The mineral liquid of this embodiment contains about 7000-13000 (ppm) of iron, and pH is about 0.1-0.2.
  Moreover, the diameter of the polymer contained in the mineral liquid of this embodiment is about 3 to 5 (nm).
[0024]
  Iron contained in the mineral liquid of the present embodiment exists in different forms depending on pH. Below pH 3, iron is Fe³⁺At pH 3 to pH 4, Fe³⁺And Fe (OH)₂ ⁺At pH 4 to pH 5, Fe³⁺And Fe (OH)²⁺And Fe (OH)₂ ⁺At pH higher than pH 5, Fe (OH)²⁺And Fe (OH)₂ ⁺And Fe (OH)₃Exists as.
[0025]
  Moreover, the residue which extracted the soil which is a base material of the mineral liquid of this embodiment with sulfuric acid contains pure iron (Fe (3+)) and amorphous goethite (α-FeOOH). Here, pure iron (Fe (3+)) refers to stable iron that does not easily change, and refers to iron that is not oxidized and does not elute.
  In the present embodiment, organic waste such as livestock excrement, raw garbage, food waste, pruned branches, waste material chips, and septic tank sludge is used as the organic matter. However, as a matter of course, organic substances other than waste may be used as the organic substances.
[0026]
  Next, the ferrihydrite humus complex according to the present embodimentOf soil recovery material consisting ofA manufacturing method will be described.
  In this production method, first, an organic matter crushing step 1 for crushing organic waste with a known shredder is performed. This crushing step 1 is a subsequent primary fermentation step, secondary fermentation / ripening step, and crushes large organic wastes in advance for the purpose of facilitating the decomposition of organic matter.
[0027]
  Subsequent to the crushing step 1, the organic substance pH adjusting step 2 is performed. In this process, slaked lime (calcium hydroxide: Ca (OH)₂) To adjust the pH of the organic substance to 5 or more. When the pH of the organic substance is 5 or more, it is not necessary to add a pH adjusting compound such as slaked lime in the pH adjusting step 2.
  Mineral liquid is Fe (OH) below pH 5₃Does not exist, Fe³⁺And Fe (OH)²⁺And Fe (OH)₂ ⁺It becomes the form. Fe³⁺And Fe (OH)²⁺And Fe (OH)₂ ⁺In the case of this form, the organic substance forms a complex with other elements such as aluminum, magnesium, and calcium instead of iron, so that ferrihydrite that is a complex of iron and organic substance cannot be formed. Therefore, in order to form ferrihydrite, it is necessary that the pH of the mixture of the organic substance and the mineral liquid diluted water is 5 or more in each process after the mineral liquid immersion process in the subsequent process..
In particularRecently, the trend of not favoring the use of aluminum has become common in society, but it is possible to prevent the formation of a complex of aluminum and organic matter by adjusting the organic matter to pH 5 or higher. Become.
  In order to set the pH to 5 or more in each step after the mineral liquid immersion step, the pH of the organic substance may be set to 5 or more in the pH adjustment step 2. Mineral liquidDilution waterIn each process after the dipping process, the mineral liquid and the organic substance are mixed.Dilution waterSince the pH is set to 5 or more in order to prevent the death of the bacteria responsible for fermentation, if the pH of the organic substance is adjusted to 5 or more in advance in this pH adjustment step 2, the pH of the mixture of the mineral liquid and the organic substance is This is because the total is 5 or more.
[0028]
  In this embodiment, the organic substance is adjusted to pH 5 or higher. However, it is more preferable to adjust the organic substance to pH 7 or higher. When the pH of the mineral liquid of this embodiment is gradually increased from a low pH, it becomes a raw material for the production of ferrihydrite.Fe (OH)₃Is started at pH 5 and reaches a substantially maximum amount at pH 7.
In the organic pH adjustment step 2, C / N adjustment is performed before the pH adjustment. C / N adjustment is performed in the same process as the process in the general compost manufacturing process. The C / N adjustment step may be performed before the crushing step 1.
[0029]
  After the pH adjustment step 2, a mineral liquid dilution water immersion step 3 is performed in which an organic substance adjusted to pH 5 or higher is immersed in a mineral liquid dilution water tank.
  In this step, first, a mineral liquid diluted water 1000 (l) is prepared by diluting the mineral liquid 5000 times with water in a water tank.
  Thus, the mineral liquid is diluted with water because the mineral liquid has a pH of about 0.1 to 0.2.organic matterAdded, the bacteria that ferment in the composting process will die, and laterPrimary fermentation (mineral liquid addition) step 4, secondary fermentation / ripening (mineral liquid addition) step 5This is because it becomes impossible to compost.
  This mineral liquid dilution water is preferably set to pH 5 to 7 in order to prevent bacterial killing.
[0031]
  An organic substance 1000 (l) adjusted to a pH of 5 or more is put into a water tank storing 5000 times mineral liquid diluted water 1000 (l) and immersed for 5 hours or more.
  By performing this mineral liquid dilution water immersion process 3, it becomes possible to advance ferrihydrite formation.
  In this process, since the pH of the mixture of the 5000 times mineral liquid diluted water and the organic substance having a pH of 5 or more is 5 or more, iron contained in the mineral liquid is a raw material for ferrihydrite.RuFe (OH)₃Thus, ferrihydrite is formed.
  Iron and sulfate radicals (SO₄ ^2-) Is known to have an effect of suppressing the growth of anaerobic bacteria, but since the mineral liquid dilution water of this embodiment contains iron and sulfate radicals, the mineral liquid dilution water immersion step By performing step 3, effects such as removal of malodor, sterilization of pathogenic bacteria and spoilage bacteria, adsorption of gas such as methane gas, and neutralization of salt can be obtained.
[0032]
  After the mineral liquid dilution water immersion process 3, a primary fermentation (mineral liquid addition) process 4 for fermenting organic matter is performed. In the primary fermentation (mineral liquid addition) step 4, a mixed solution preparation step and a mixing step are performed as described below.
  In primary fermentation (mineral liquid addition) step 4, a mixed liquid preparation step is performed in which a fermentation aid for addition to an organic substance and mineral liquid diluted water are mixed in advance. In the mixed liquid preparation step, a mineral liquid diluted water 100 (l) having a pH of about 3.5 obtained by diluting the mineral liquid with water 10,000 times is poured into a water tank (not shown). Next, 1 kg of fermentation aid containing microbial material, enzyme material, etc. is put into this water tank and mixed. Thereafter, aeration is performed by a known method for 12 hours to obtain a mixed solution. As fermentation aids, commercially available fermentation aids containing aerobic bacteria such as filamentous fungi and lactic acid bacteria, anaerobic bacteria such as fiber-degrading bacteria, and enzymes such as amylase (trade name: Microzyme, manufactured by Rion Co., Ltd.) F) is used.
[0033]
  In the present embodiment, the fermentation aid is added to the mineral liquid dilution water for the following reason. General organic waste contains substances such as salt, oil, and chemical substances, and smooth fermentation may be hindered by these substances, so add a fermentation aid to the mineral liquid dilution water, Smooth fermentation is performed. In addition, you may add the cut-back goods which finished primary fermentation as a return compost instead of a fermentation adjuvant.
[0034]
  After performing the mixed solution preparation step, the mixing step of adding the mixed solution to the organic substance and stirring and mixing is performed by the blender 11 of FIGS. 2 is a view of the blender 11 as viewed obliquely from above, and FIG. 3 is a cross-sectional view of the blender 11. As shown in FIG.
  The blender 11 includes a fermenter 13 for storing organic matter, a hopper 12 that is an inlet for introducing organic matter, a pipe 15 for introducing a mixed solution, a cutter 14 for stirring organic matter, and air. And a fan (not shown) for introduction.
[0035]
  As shown in FIG. 2, the cutter 14 includes a cutter shaft 14a extending in the longitudinal direction of the fermenter 13 and cutter blades 14b fixed radially around the cutter shaft 14a. The cutter shaft 14a is not shown. The cutter blade 14b is agitated so as to cut the organic matter stored in the fermenter 13 by being rotated by this motor.
  As shown in FIG. 3, a plurality of pipes 15 are fixed near the upper wall in the fermenter 13 so as to be orthogonal to the longitudinal direction of the fermenter 13. A plurality of holes (not shown) are formed in each pipe 15, and the mixed liquid passing through the pipe 15 can be sprayed into the fermenter 13 from the holes.
  In addition, although FIG. 2 is drawn so that the wall surface of the right front side of the fermenter 13 may be opened, it is for ease of understanding and is closed during the mixing step.
[0036]
  In the mixing step, first, an organic substance is put into the fermenter 13 from the hopper 12. Thereafter, the cutter 14 is rotated and agitated by a motor (not shown). Next, the mixed solution 100 (l) is sprayed from the pipe 15 while stirring. Thereafter, the mixture is further stirred for 0.5 to 1 hour.
  In this embodiment, in the primary fermentation (mineral liquid addition) step 4, the fermentation assistant is added to the mixed solution, but only the mineral liquid dilution water is added to the organic matter without adding the fermentation assistant. May be.
  Further, in this embodiment, the mixing process is performed using a horizontal type blender 11 of a horizontal type, that is, a horizontally long cylindrical body having a semicircular cross section. It is only necessary to use an apparatus, and other known mixing apparatuses such as a vertical type, a multistage type blender, a round type, a rectangular parallelepiped type blender, and a drum type blender may be used.
[0037]
  After the primary fermentation (mineral liquid addition) step 4, the organic matter is taken out from the blender 11, and the secondary fermentation / ripening (mineral liquid addition) step 5 is performed.
  In the secondary fermentation / ripening (mineral liquid addition) step 5, the organic liquid taken out from the blender 11 is further deposited in the compost with a roof and fermented, and further diluted with mineral liquid.
  The organic matter taken out from the blender 11 has already started fermentation and has a considerably high temperature. In secondary fermentation and complete ripening (mineral liquid addition) step 5, when the temperature of the organic substance reaches 65 ° C to 70 ° C, replenishment of mineral liquid dilution water while switching back by stirring using a bulldozer, excavator, etc. I do.
[0038]
  The switching timing varies depending on the season, but is usually performed as follows. That is, after organic matter is deposited and secondary fermentation / ripening (mineral liquid addition) process 5 is started, the temperature of the organic substance becomes about 70 ° C. around three days later, and the mineral liquid diluted water is sprayed and turned over. After spraying and turning over, the temperature once decreases, but since the temperature of the organic substance becomes about 70 ° C. around the 10th day and the 17th day from the start of the secondary fermentation / ripening (mineral liquid addition) process 5, the mineral liquid Sprinkle with diluted water. Thereafter, the organic matter becomes fully-ripened compost in about 3 weeks from the start of the secondary fermentation / ripening (mineral liquid addition) step 5.
  The mineral solution diluted water to be sprayed is 7000 times diluted water of the mineral solution, and the spray amount is about 10% by weight of the organic matter amount.
  The mineral water dilution water is added for the purpose of supplying iron for forming ferrihydrite.
  When diluting the mineral liquid, it is necessary to sufficiently stir by turning over and supply oxygen sufficiently. This is because iron is eluted in a divalent state under anaerobic conditions, and trivalent iron necessary for ferrihydrite formation is reduced.
  By the steps up to the above-mentioned secondary fermentation / ripening (mineral liquid addition) step 5, it is completed as a fully-ripened fermented compost and a normal soil improvement material.
[0039]
  After the secondary fermentation / ripening (mineral liquid addition) step 5, the post-composting mineral addition step 6 of the fully-ripened organic compost is performed.
  In the mineral addition step 6 after composting, first, organic compost is put into the blender 11 of FIG. 2 and stirring is started. Stirring is performed while maintaining the temperature in the blender 11 at 40 to 50 ° C, preferably 40 to 45 ° C. While stirring, the blender 11 is sprayed with 10% by weight of the amount of compost of the mineral liquid 5000 times and further stirred to evaporate water contained in the organic compost. At this time, you may perform the mineral addition process 6 after composting, introducing air with a fan not shown.
[0040]
  The procedure of evaporating water while spraying this mineral liquid 5000 times diluted water is repeated 5 times to complete the mineral addition step 6 after composting. In the mineral addition step 6 after composting, the water content is also adjusted so that the water content of the obtained organic compost becomes appropriate for fermentation. In the soaking process 3 to the mineral addition process 6 after composting, since the mineral liquid dilution water is sprayed, the amount of water in the organic compost increases, and this moisture is evaporated to obtain an appropriate amount of water as compost. is there. If the amount of water in organic compost is large, various components contained in organic compost will dissolve.Take offTherefore, usually in this step, the water content in the organic compost is adjusted so that the water content is 10 to 20% by weight, preferably about 12%.
  With the above, ferrihydrite humus complexOf soil recovery material consisting ofThe manufacturing method is completed.
  Then, if necessary, perform packaging, etc., and ferrihydrite humus complexSoil restoration material consisting ofProduct.
[0041]
  The ferrihydrite humus complex produced in this embodiment can be used as a soil recovery material for purifying problem contaminated soils such as heavy metals, harmful polymer organic compounds, salt damage, residual agricultural chemicals and harmful chemicals It is. When used as a soil recovery material, the ferrihydrite humus complex produced in the present embodiment is used by mixing with problem-contaminated soil.
  Moreover, the ferrihydrite humus complex manufactured by this embodiment can also be used as a pollution purification material of a river or a lake. Adsorption ability and catalytic ability peculiar to ferrihydrite humus complex promotes aggregation of suspensions mainly composed of organic substances that float and settle in rivers and lakes, and also forms complex precipitates with phosphate compounds, improving water quality transparency. Is planned.
[0042]
  Ferrihydrite humus complex of this embodimentOf soil recovery material consisting ofIn the manufacturing method, since the pH of the organic substance is adjusted to 5 or more in the pH adjustment process 2 before the mineral liquid dilution water immersion process 3, when the organic substance is immersed in the mineral liquid dilution water, the mineral liquid dilution water is used. It becomes possible to make the pH of the ferrihydrite raw material in diluted mineral water.RuFe (OH)₃(Iron hydroxide) can be present. As a result, it is possible to prevent the organic substance from forming a complex with other elements such as aluminum and magnesium. The humus complex can contain iron that has a very low possibility of adversely affecting living organisms and ecosystems. Furthermore, it is possible to form a humus complex containing ferrihydrite which has a large surface area where the reaction occurs and a large physicochemical reaction force due to the mutation charge characteristic caused by pH change.
[0043]
  In addition, ferrihydrite is known to have an antioxidant effect due to oxygen adsorption, a meat freshness retaining effect, an antibacterial / antibacterial effect due to anaerobic bacterial growth inhibition, and the like. Hydrite humus complex also has these effects.
  Ferrihydrite humus complex according to this embodimentOf soil recovery material consisting ofIn the production method, Fe in mineral liquid³⁺Ion,Mineral liquid dilution waterIn the process of depositing by decreasing the positive valence due to the pH increase in the soaking process 3 and post-composting mineral addition process 6, amorphous ferrihydrite that is not crystallized is formed due to the high deposition rate. It is a thing. As already described, this ferrihydrite is an amorphous hydrated oxide with a chelate bond.
[0044]
  In addition, the composition of an example of the mineral liquid used by this embodiment is shown in FIG.
  Moreover, as a result of measuring an example of a residue obtained by extracting the mineral liquid used in the present embodiment with sulfuric acid by Mossbauer spectroscopy, it is found that paramagnetic Fe (3+) and Fe at the spinel octahedron position₃O₄Spinel tetrahedron Fe₃O₄And α-Fe₂O₃It was found to contain. Of the Fe contained in the residue, 6% is paramagnetic Fe (3+), 38% is spinel-octahedral Fe₃O₄, 31% is spinel and tetrahedral Fe₃O₄, 25% α-Fe₂O₃The measurement result was obtained.
[0045]
Example 1
  Hereinafter, the Example which manufactured the ferrihydrite humus composite_body | complex is demonstrated.
  In this example, Clay Extract W. manufactured by Rion Co., Ltd. is used as the mineral liquid. W was used.
  The procedure of the manufacturing method of this example will be described.
  First, C / N adjustment was performed on organic waste obtained from a general garbage disposal site, and organic waste 1000 (l) was prepared. Next, the organic waste was crushed with a known shredder and subjected to organic crushing step 1. Then, the pH was measured to be 6.0. Therefore, 0.5 kg of slaked lime was added to adjust the pH of the organic substance to 7.0, and pH adjustment step 2 was performed.
[0046]
  Subsequently, 1000 times (1) of 5000 times dilution water of a mineral liquid was prepared in the water tank, and the organic substance was immersed in this mineral liquid dilution water for 5 hours, and the mineral liquid dilution water immersion process 3 was performed.
  Then, the primary fermentation (mineral liquid addition) process 4 which ferments organic substance was performed.
In this step 4, firstly, a water tank is charged with 10000-fold diluted water 100 (l) (pH of about 3.5) and 1 kg of fermentation aid (product name: Microzyme F, manufactured by Rion Co., Ltd.) and mixed. Let Thereafter, aeration was performed by a known method for 12 hours to prepare a mixed solution. The mixed liquid 100 (l) was sprayed while stirring after the organic substance was added to the blender 11. Thereafter, the mixture was further stirred for 1 hour.
  Next, the organic matter is taken out from the blender 11, deposited in a compost with a roof, and sprinkled with a bulldozer while spraying 300 (l) of a 7000-fold diluted mineral solution in three batches of 100 (l). Next fermentation / ripening (mineral liquid addition) step 5 was performed. The amount of organic matter at this time was about 1000 kg. In this step 5, a fully-ripened organic compost was obtained.
[0047]
  Then, the mineral addition process 6 was performed after composting. In this step 6, the organic compost is put into the blender 11, the temperature in the blender 11 is maintained at 43 ° C., and the mineral liquid 5000 times diluted water 100 (l) is sprayed while stirring, and the procedure for further stirring is repeated five times. Repeatedly.
  Through the above steps, 400 kg of ferrihydrite humus composite having a water content of about 12% was obtained.
[0048]
  When CEC (cation exchange capacity) was measured by the ammonium acetate method of the fertilizer analysis method using 50 g of the completed ferrihydrite humus complex as a sample, the CEC was 78 (meq).
  Those having a CEC of 30 (meq) or more are generally known to contain ferrihydrite, soPlantingIt was demonstrated that the complex contained ferrihydrite.
[0049]
  The amount of ferrihydrite produced in the process of producing the ferrihydrite humus composite of this example is roughly as follows.
  In each step, the following amount of mineral liquid is added to the organic waste 1000 (l) used in this example.
  Mineral liquid dilution waterIn dipping process 3, mineral liquid 5000 times diluted water 1000 (l), in primary fermentation (mineral liquid addition) process 4, mineral liquid 10000 times diluted water 100 (l), secondary fermentation and complete ripening (mineral liquid addition) In step 5, about 100 (l) of 7000 times diluted mineral liquid is added three times, and in step 6 of adding minerals after composting, about 100 (l) of diluted water of 5000 times diluted mineral liquid is added. When this is converted into the amount of mineral liquid stock solution,Mineral liquid dilution waterIn immersion process 3, mineral liquid 200 (ml), in primary fermentation (mineral liquid addition) process 4, mineral liquid 10 (ml), in secondary fermentation / ripening (mineral liquid addition) process 5, mineral liquid about 45 (ml), compost In the mineral addition step 6 after the formation, a mineral liquid 100 (ml) is added.
  Therefore, about 355 (ml) is added in all steps.
  This is a trial calculation assuming that the amount of organic matter is 1000 (l), and the weight loss due to gasification decomposition of the organic matter is ignored.
[0050]
  As a result of analysis by o-phenanthroline spectrophotometry, it is known that about 10 (g) of iron is contained in the mineral liquid stock solution 1 (l). Moreover, it is proved by experiment that iron 1 (g) corresponds to about 1.5 (g) ferrihydrite.
  From the above, in this example where 355 (ml) mineral liquid stock solution was added in all steps, about 5 (g) ferrihydrite was formed from 15 (g / l) × 0.355 (l). The Rukoto.
  The specific surface area of ferrihydrite is about 200 (m²/ G), the surface area of ferrihydrite in the ferrihydrite humus complex of 1 (t) is 5 (g) × 200 (m²/ G), about 1000 (m²)
[0051]
[Industrial use]
  As described above, according to the present invention, the ferrihydrite humus complexOf soil recovery material consisting ofIn the manufacturing method,organic matterFe (OH) contained in the mineral liquid because the primary fermentation process, secondary fermentation / ripening process, and the mineral addition process after composting are performed.₃Whenorganic matterAnd ferrihydrite that can be used as a soil recovery materialHumus complexCan be formed.
  Moreover, since the pH adjustment process is performed,Mineral aqueous solution immersion process, primary fermentation process, secondary fermentation / ripe processIn this case, the iron contained in the mineral liquid aqueous solution is converted to Fe (OH) which is a raw material for ferrihydrite.₃Thus, ferrihydrite can be formed.
In addition, since the pH of the organic substance is adjusted to 5 or more in the pH adjustment step before the mineral liquid aqueous solution immersion step, the mineral liquid aqueous solution can have a pH of 5 or more in the mineral liquid aqueous solution immersion step. , Fe (OH) used as ferrihydrite raw material in mineral liquid aqueous solution ₃ (Iron hydroxide) can be present. As a result, the organic substance can be prevented from forming a complex with other elements such as aluminum and magnesium. The humus complex can contain iron that has a very low possibility of adversely affecting living organisms and ecosystems. Furthermore, it is possible to form a humus complex containing ferrihydrite having a large surface area where the reaction occurs and a large physicochemical reaction force due to the mutation charge characteristic caused by pH change.
[0052]
  Primary fermentation process, secondary fermentation / ripe processAt the same time as the addition of the mineral aqueous solution,organic matterTherefore, ferrihydrite humus composites having performance as general compost as well as performance as soil recovery material peculiar to ferrihydrite can be produced.
  Also according to the invention,pH 5-7In the presence of an aqueous solution of mineral acid extract from sedimentary rock soil,organic matterFormed by fermentingAs well as being fully ripe organic compost,Ferrihydrite humus complexSoil restoration material consisting ofBecause,NothingThe machine acid extract isIt contains the most iron among metals, and at a pH of 3 or less, ³⁺ At pH 3 to pH 4, Fe ³⁺ And Fe (OH) ₂ ⁺ At pH 4 to pH 5, Fe ³⁺ And Fe (OH) ²⁺ And Fe (OH) ₂ ⁺ At pH higher than pH 5, Fe (OH) ²⁺ And Fe (OH) ₂ ⁺ And Fe (OH) ₃ Including asTherefore, it becomes possible to obtain a ferrihydrite humus complex having a performance as a general compost in addition to the performance as a soil recovery material peculiar to ferrihydrite. Ferrihydrite has a specific surface area of about 200 (m²/ G) and a large field for reaction with the OH end and O end of the organic compound, so that it is possible to obtain a soil recovery material with high catalytic ability and ability to form aggregates. Become.
  Moreover, since this ferrihydrite humus complex contains the mineral derived from an inorganic acid extract, it becomes possible to obtain a soil recovery material capable of promoting the activity of microorganisms and enzymes and improving the environment of microorganisms.
[0053]
[Brief description of the drawings]
FIG. 1 shows the ferrihydrite humus complex of the present invention.Of soil recovery material consisting ofFIG. 2 is a block diagram illustrating a flow of an embodiment of a manufacturing method, and FIG. 2 is a ferrihydrite humus composite according to the present invention.Of soil recovery material consisting ofManufacturing methodPrimary fermentation process3 is an explanatory view showing an example of a blender used in a mineral addition step after composting, FIG. 3 is a cross-sectional explanatory view of the blender shown in FIG. 2, and FIG. 4 is a ferrihydrite humus composite of the present invention.Of soil recovery material consisting ofIt is a table | surface which shows the composition of the mineral liquid used with a manufacturing method.

Claims (11)

A pH adjusting step for adjusting the pH of the organic substance to 5 or more;
While oxygen fed while maintaining the pH of the organic material to 5 or more, the organic matter comprises most of the iron in the metal, the iron is in the solution, at a pH higher than p H5, F e (OH) 3 exist, the mineral solution at least one sedimentary soil consisting of the group obtained by extraction with inorganic acids including basalt and andesite, mineral liquid aqueous solution adjusted to pH 5-7, and minerals liquid aqueous immersion step of immersing a,
A primary fermentation step of sprinkling a mixed solution of a mineral liquid aqueous solution obtained by diluting the organic liquid with a fermentation aid and the mineral liquid while maintaining the pH of the organic substance at 5 and stirring the organic substance;
A mineral liquid aqueous solution in which the mineral liquid is diluted with water while maintaining the pH of the organic substance at 5 or more and depositing and fermenting the organic substance in a compost and turning the organic substance when it reaches a predetermined temperature. A method for producing a soil restoration material comprising a ferrihydrite humus complex, comprising: a secondary fermentation / ripening step that is applied to obtain a fully fermented compost. The said predetermined temperature is 65 degreeC or more. The manufacturing method of the soil recovery material which consists of ferrihydrite humus composites of Claim 1 characterized by the above-mentioned. After the secondary fermentation / ripe process, at 40 to 50 ° C., the mineral liquid aqueous solution is sprayed while stirring the fully fermented compost and the post-composting mineral addition process is performed to adjust the water content of the fully fermented compost. The manufacturing method of the soil recovery material which consists of a ferrihydrite humus complex of Claim 1 characterized by the above-mentioned. In the said pH adjustment process, pH of the said organic substance is adjusted to 7 or more. The manufacturing method of the soil recovery material which consists of a ferrihydrite humus complex of Claim 1 characterized by the above-mentioned. The method for producing a soil restoration material comprising a ferrihydrite humus complex according to claim 1, wherein C / N adjustment of the organic matter is performed before the pH adjustment step. The soil comprising the ferrihydrite humus complex according to claim 1, wherein the primary fermentation step and the secondary fermentation / ripening step are performed while maintaining iron in the mineral liquid aqueous solution in a trivalent state. Recovery material manufacturing method. 2. The ferrihydrite humus complex according to claim 1, wherein the sum of the amount of magnesium and the amount of calcium contained in the mineral liquid is less than 30% by weight of the amount of iron contained in the mineral liquid. The manufacturing method of the soil restoration material which becomes. Before the pH adjustment step, perform an inorganic acid extraction step of preparing the mineral liquid by extracting at least one sedimentary rock soil consisting of a group including basalt and andesite with an inorganic acid,
The ferritic acid according to claim 1, wherein, in the inorganic acid extraction step, a residue containing pure iron (Fe (3+)) and amorphous goethite (α-FeOOH) and the mineral liquid are obtained. A method for producing a soil restoration material comprising a hydrite humus complex. A fully fertilized organic compost produced by fermenting organic matter in the presence of an aqueous solution of an inorganic acid extract of sedimentary rock soil having a pH of 5 to 7 produced by the production method of claim 1 , and a ferrihydrite humus complex A soil restoration material consisting of
The inorganic acid extract, with the highest concentration of iron in the metal, the iron, higher than p H5 pH, consisting of ferrihydrite humus complex which comprises as an F e (OH) ₃ Soil restoration material. 10. The ferrihydrite according to claim 9, wherein the sum of the amount of magnesium and the amount of calcium contained in the inorganic acid extract is less than 30% by weight of the amount of iron contained in the inorganic acid extract. Soil restoration material consisting of humus complex. The soil recovery material comprising the ferrihydrite humus complex according to claim 9, wherein the moisture content is 10 to 20% by weight.

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