JP2013107966A - Soil solidifying material - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a soil solidifying material enabling to increase blending of recycling materials, though lower alkaline than before, while suppressing elution of hexavalent chromium.SOLUTION: The soil solidifying material includes blast furnace cement, paper sludge ash, waste gypsum (taken from waste gypsum board) and ferrous sulfate. When the blast furnace cement is set to 50 pts.mass, the paper sludge ash may be 25-35 pts.mass, the waste gypsum may be 15-30 pts.mass and the ferrous sulfate may be 1-2 pts.mass. In addition, light-burned magnesia may be contained.

Description

  The present invention relates to a soil solidifying material, and more particularly to a soil solidifying material using waste gypsum.

  In recent years, attempts to recycle waste are being promoted in various fields, and in the field of soil improvement, waste gypsum collected from gypsum board discharged with construction demolition, etc., and discharged from paper mills, etc. A technique for blending paper sludge ash, which is incinerated ash of paper sludge, into a cement-based soil improvement material has attracted attention. In the cement-based soil conditioner containing these two types, waste gypsum and paper sludge ash act upon the hydration reaction of cement to form ettringite. When ettringite is formed, moisture in the soil is taken in as hydrated water to reduce the amount of moisture in the soil, and the soil can be solidified. The following Patent Document 1 and Patent Document 2 are known as cement-based soil improvement materials using both waste gypsum and paper sludge ash.

JP 2009-185220 A JP-A-2005-344031

However, both of the techniques of Patent Document 1 and Patent Document 2 described above use Portland cement as a cement component, and the amount of waste gypsum is reduced to 10% by mass while keeping the elution amount of hexavalent chromium sufficiently small. There is a problem that it is difficult to blend in excess. In addition, because there is a lot of Portland cement, it tends to be strongly alkaline, and it is possible to suppress elution of hexavalent chromium even at a lower pH, and the mixing ratio of recycled components such as waste gypsum and paper sludge ash There is a demand for a soil-solidifying material having a larger size and superior environmental characteristics.
The present invention has been made in view of the above circumstances, and provides a soil-solidifying material capable of increasing the amount of recycled components while suppressing the elution of hexavalent chromium and being lower in alkali than in the past. With the goal.

In order to solve the above problem, the soil solidifying material according to claim 1 contains blast furnace cement, paper sludge ash, waste gypsum, and ferrous sulfate.
The soil-solidifying material according to claim 2, when the blast furnace cement is 50 parts by mass in claim 1, the paper sludge ash is 25 to 35 parts by mass, the waste gypsum is 15 to 30 parts by mass, The gist is that the ferrous sulfate is 1 to 2 parts by mass.
The gist of the soil-solidifying material according to claim 3 is that of claim 1 or 2, further comprising light-burned magnesia.
According to a fourth aspect of the present invention, there is provided a soil solidifying material according to any one of the first to third aspects, wherein the blast furnace cement is a B-type blast furnace cement.

According to the soil solidifying material of the present invention, it is possible to effectively use three types of wastes, such as blast furnace slag, paper sludge ash, and waste gypsum, and to obtain a soil solidifying material having a high blending ratio of recycled components. Furthermore, it is possible to make the alkali lower than in the prior art while suppressing elution of hexavalent chromium. That is, a soil solidifying material having excellent environmental characteristics can be obtained.
When the blast furnace cement is 50 parts by mass, the paper sludge ash is 25 to 35 parts by mass, the waste gypsum is 15 to 30 parts by mass, and the ferrous sulfate is 1 to 2 parts by mass. In addition, it is possible to obtain a soil solidifying material having a high blending ratio of waste gypsum and a large ratio of recycled components. That is, excellent environmental performance can be obtained.
Furthermore, when lightly burned magnesia is contained, elution of hexavalent chromium can be suppressed, and even when the paper sludge ash contains fluorine, elution of the fluorine can be suppressed.
If the blast furnace cement is Class B blast furnace cement, the blending ratio of paper sludge ash and waste gypsum can be increased, and blast furnace cement with a large amount of blast furnace slag will be used. It can be a material. That is, it can be set as the soil solidification material which has the outstanding environmental performance.

Hereinafter, the present invention will be described in detail.
The soil-solidifying material of the present invention contains (1) blast furnace cement, (2) paper sludge ash, (3) waste gypsum, and (4) ferrous sulfate.

  The “(1) blast furnace cement” is cement containing blast furnace slag. This blast furnace cement exhibits latent hydraulic properties due to blast furnace slag, and has a hardened structure that is superior in strength properties, chemical durability and water tightness compared to Portland cement (a structure in which soil particles in the soil promote aggregation) ) Can be obtained. The kind of blast furnace cement used in the present invention is not particularly limited. When the entire blast furnace cement is 100% by mass, the blending ratio of blast furnace slag can be 5 to 70% by mass. It is preferable that it is mass%, and it is more preferable that it is 40-70 mass%. When the ratio of the blast furnace slag is 30% by mass or more (further 40% by mass or more), the alkali silica reaction is suppressed, and a hardened structure having particularly excellent durability can be obtained. Specifically, the blast furnace cement is preferably a B-type blast furnace cement (blast furnace slag 30 to 60% by mass) or a C-type (blast furnace slag 60 to 70% by mass) blast furnace cement. A seed blast furnace cement is more preferred.

The “(2) paper sludge ash” is incinerated ash of paper sludge. Paper sludge is sludge generated mainly when recycling used paper in the papermaking process, and includes short fibers, pigments, talc and the like. The residue resulting from incineration of this paper sludge is paper sludge ash. Paper sludge ash is rich in silicon-based components (particularly SiO ₂ ), aluminum-based components (particularly Al ₂ O ₃ ), and calcium-based components (particularly CaO). The paper sludge ash by a hydration reaction with gypsum will be described later, can form crystalline water often ettringite _{(3CaO · Al 2 O 3 ·} 3CaSO 4 · 32H 2 O). For this reason, while promoting the agglomeration of soil particles even in soil with a large amount of moisture, the moisture in the soil is taken in as crystal water of ettringite, reducing the moisture content in the soil, and increasing the strength of the soil Can do.

  The paper sludge ash used in the present invention may be any paper sludge ash, and the paper sludge ash includes those that elute fluorine and those that do not substantially elute fluorine. Among these, when using paper sludge ash having a property of eluting fluorine, it is preferable to blend “(5) light-burned magnesia” in the soil-solidifying material of the present invention.

  This light-burned magnesia is a component obtained by calcination (for example, heating at 600 to 900 ° C.) of a magnesium carbonate mineral or magnesium hydroxide, and contains magnesium oxide (usually 40 to 85% by mass, 100 It may be mass%). By blending light-burned magnesia, the elution of hexavalent chromium can be suppressed to a higher degree than when not blended, and the elution of fluorine can be suppressed simultaneously. Furthermore, when lightly burned magnesia is blended, the lightly burned magnesia itself can exhibit curing characteristics. That is, it changes to magnesium carbonate by a hydration reaction and can form a soil component and a hardened tissue by a polazone reaction or the like. The light-burned magnesia used in the present invention may itself be a waste. For example, waste light-burned magnesia used for flue gas desulfurization can be used.

  Further, dolomite or a processed product thereof (light-burned dolomite, dolomite clicker, etc.) can be used instead of light-burned magnesia. Light-burned dolomite is a component obtained by calcining dolomite (for example, 1500 to 1800 ° C.), and dolomite clinker is a component obtained by calcining dolomite (for example, 1300 to 1450 ° C.), Contains magnesium oxide. Light-burned dolomite can be made to act in the same manner as light-burned magnesia, and it can suppress elution of hexavalent chromium to a higher degree and simultaneously suppress elution of fluorine. Furthermore, curing characteristics can be expressed with a polazone reaction or the like. Further, when dolomite or a processed product thereof is used in the present invention, the dolomite itself may be a waste.

  The above “(3) waste gypsum” is gypsum (calcium sulfate dihydrate) collected from waste gypsum products and calcined gypsum (calcium sulfate hemihydrate). Specifically, gypsum collected from waste gypsum board, various gypsum products and discarded gypsum generated in the production process thereof, and calcined products of these gypsum, and the like. These may use only 1 type and may use 2 or more types together. In the soil solidification material of this invention, since the mixture ratio of gypsum can be made high compared with the past, the shrinkage | contraction behavior by a blast furnace cement can be suppressed.

  The “(4) ferrous sulfate” functions as a reducing agent even in an alkaline environment, and can be stabilized as trivalent chromium by suppressing oxidation of chromium ions to hexavalent. In the soil-solidifying material of the present invention, the cement component is reduced by reducing the proportion of the cement component by using each recycled component (blast furnace slag, paper sludge ash and waste gypsum) having a lower alkalinity than the cement component. In addition to reducing the amount of chromium contained in the alkali, the alkalinity can be kept low. As a result, the reducing action of ferrous sulfate can be sufficiently exerted, and elution of hexavalent chromium can be suppressed extremely low. Moreover, since alkalinity can be restrained low as above-mentioned, the improvement soil obtained using this soil solidification material has a quick recovery | restoration of pH (it returns to the neutral region of pH 5.5-8.5). Vegetation can be recovered early in the improved soil obtained.

The ferrous sulfate used in the present invention may be in any hydrated state. Namely, anhydrous (FeSO ₄ ), monohydrate (FeSO ₄ · H ₂ O), tetrahydrate (FeSO ₄ · H ₂ O), pentahydrate (FeSO ₄ · 5H ₂ O), seven Any of hydrates (FeSO ₄ · 7H ₂ O) can be used, and these may be used alone or in combination of two or more. Furthermore, as the ferrous sulfate used in the present invention, high-purity ferrous sulfate may be used, but so-called industrial ferrous sulfate (hereinafter simply referred to as “industrial iron sulfate”) may be used. . Industrial iron sulfate is a component containing ferrous sulfate recovered from pickling wastewater discharged in the iron making process or the like. In addition, when using industrial iron sulfate, content of ferrous sulfate is although it does not specifically limit, Usually, it is 45-95 mass%.

  In the present invention, the content ratio of (1) blast furnace cement, (2) paper sludge ash, (3) waste gypsum, and (4) ferrous sulfate is not particularly limited. Is 100% by mass, (1) blast furnace cement, (2) paper sludge ash, (3) waste gypsum, and (4) ferrous sulfate in a total of 90 to 100% by mass.

Furthermore, in the present invention, the blending ratio of (1) blast furnace cement, (2) paper sludge ash, (3) waste gypsum, and (4) ferrous sulfate is not particularly limited, but (1) blast furnace cement When it is 50 parts by mass, (2) 25 to 35 parts by mass of paper sludge ash, (3) 15 to 30 parts by mass of waste gypsum, (4) ferrous sulfate (converted as FeSO _{4 having a} purity of 100%) In the case) is preferably 1 to 2 parts by mass. This blending amount further includes (1) 50 mass parts of blast furnace cement, (2) 27-32 mass parts of paper sludge ash, (3) 17-21 mass parts of waste gypsum, (4) sulfuric acid It is more preferable that ferrous iron (when converted as FeSO _{4 having a} purity of 100%) is 1 to 1.5 parts by mass.
Furthermore, as described above, when (5) light burned magnesia is contained, (1) when the blast furnace cement is 50 parts by mass, (5) light burned magnesia (when converted to MgO having a purity of 100%) It is preferably 0.1 to 1.5 parts by mass, more preferably 0.2 to 1.2 parts by mass, and more preferably 0.3 to 0.7 parts by mass.

Hereinafter, the present invention will be specifically described with reference to examples.
[1] Preparation of soil solidifying material <Example 1>
(1) 50 parts by mass of blast furnace cement, (2) 30 parts by mass of paper sludge ash (no elution of fluorine), (3) 19 parts by mass of waste gypsum, (4) ferrous sulfate (as 100% pure FeSO ₄ Each component was weighed and mixed so as to be 1.2 parts by mass (when converted), and the soil solidifying material of Example 1 was obtained.

<Example 2>
(2) Blast furnace cement 50 parts by mass, (2) Paper sludge ash (with fluorine elution) 30 parts by mass, (3) Waste gypsum 19 parts by mass, (4) Ferrous sulfate (as 100% pure FeSO ₄ Each component was weighed and mixed so that it would be 1.2 parts by mass (when converted) and (5) 1 part by mass of light-burned magnesia (product name “Mugguard S” manufactured by Ube Industries, Ltd.) Two soil-solidifying materials were obtained.

[2] Uniaxial compression test (1) Uniaxial compression test (using the soil-solidifying material of Example 1)
For the reinforced soil (moisture content: 17.08%, clay having a wet density of 2.134 g / m ³ ), the soil solidifying material of Example 1 obtained in the above [1] was mixed at a rate of 50 kg / m ³ , 80 kg / ^Three test specimens, each of which was mixed at a ratio of m ^{3 and} a ratio of 110 kg / m ³ (sufficiently stirred and mixed with a soil mixer and tamped 12 times with a 5 cm diameter mold), were each formed into three bodies, After curing for 7 days, it was subjected to a uniaxial compression test in accordance with JIS A1216. As a result, the average uniaxial compressive strength of the specimen by each formulation is 1244kN / ^{m 2} at ^{413kN / m 2, 110kg / m} 3 formulated in ^{149kN / m 2, 80kg / m} 3 formulated in 50 kg / ^{m 3} formulation, Excellent reinforcing effect.

[3] Evaluation of hexavalent chromium elution amount (1) Hexavalent chromium elution amount (using the soil solidifying material of Example 1)
For the soil-solidifying material of Example 1 obtained in [1] above, the test method defined in the Environmental Agency Notification No. 46 “Environmental Standards Concerning Soil Contamination” in 1991 {in accordance with Standard 65.2.1 It was less than 0.01 mg / L when the elution amount of hexavalent chromium was measured based on the method defined (diphenylcarbazide absorptiometric method of JIS K0102)}. Furthermore, when the same measurement was performed on the specimen subjected to the uniaxial compression test of [2], it was less than 0.01 mg / L.

(2) Hexavalent chromium elution amount (using the soil solidifying material of Example 2)
For the soil-solidifying material of Example 2 obtained in [1] above, the test method defined in the Environmental Agency Notification No. 46 “Environmental Standards Concerning Soil Contamination” in 1991 {in accordance with Standard 65.2.1 It was less than 0.01 mg / L when the elution amount of hexavalent chromium was measured based on the method defined (diphenylcarbazide absorptiometric method of JIS K0102)}.

(3) Hexavalent chromium elution amount (using the soil solidification material of the comparative example)
As a soil solidifying material of the comparative example, about the soil solidifying material manufactured by Sumitomo Osaka Cement Co., Ltd., the product name “Toughlock 3E type (TL-3E)”, Environmental Agency Notification No. 46 “Environmental Standards Concerning Soil Contamination” The amount of elution of hexavalent chromium based on the test method {method defined in Standard 65.2.1 (JIS K0102 diphenylcarbazide absorptiometry)} was determined to be 0.55 mg / L. It was.

[4] Evaluation of fluorine elution amount Fluorine elution amount (using the soil solidifying material of Example 2)
About soil solidification material of Example 2 obtained in the above [1] (example using paper sludge ash with fluorine elution), Environment Agency Notification No. 46 “Environmental Standards Concerning Soil Contamination” The content of hexavalent chromium based on the test method {method defined in Standard 34.1 (lanthanum-alizarin complexone absorptiometry)} was determined to be 0.38 mg / L (Sample 1; 53 mg / L, sample 2; 0.43 mg / L, sample 3; average of 0.17 mg / L). This result is a value well below 0.8 mg / L which is the soil environment standard.

[5] pH measurement test (1) Time-dependent measurement of pH of improved soil using soil-solidifying material of Example 1 The soil-solidifying material of Example 1 obtained in [1] above was reinforced soil (water content ratio 17. An improved soil was prepared by mixing 35 kg / m ³ of the soil-solidifying material of Example 1 obtained in [1] above with respect to (08% clay with a wet density of 2.134 g / m ³ ). This improved soil was put into a plastic container having a volume of 1000 mL and having approximately 5 mm diameter through-holes drilled at approximately 22 locations at the bottom, and left outdoors for 2 months. Then, the pH in each of the following periods was measured. The test method (method defined in Standard 12.1) defined in 1991 Environment Agency Notification No. 46 “Environmental Standards Concerning Soil Contamination” was used. As a result, the pH on the first day was 10.0 (temperature 25.0 ° C.), the pH after 1 week was 9.6 (temperature 23.6 ° C.), the pH after 1 month was 8.8 (temperature 26.0 ° C.), 2 After a month, the pH was 7.7 (temperature 24.8 ° C.). That is, it was found that the pH was lowered to the neutral range in about one month, and the pH was lowered very quickly. During the pH measurement, 0-day rain was observed by the first week, 1-day rain was observed by the first month, and 1-day rain was observed by the second month. The number of days of the rainy day is based on data measured by the Japan Meteorological Association. However, there are actually days when the weather is unstable. there were.

Claims (4)

  A soil solidifying material comprising blast furnace cement, paper sludge ash, waste gypsum, and ferrous sulfate.   When the blast furnace cement is 50 parts by mass, the paper sludge ash is 25 to 35 parts by mass, the waste gypsum is 15 to 30 parts by mass, and the ferrous sulfate is 1 to 2 parts by mass. The soil solidifying material described.   Furthermore, the soil solidification material of Claim 1 or 2 containing light-burned magnesia.   The soil solidifying material according to any one of claims 1 to 3, wherein the blast furnace cement is a B-type blast furnace cement.