JP3810350B2 - Cement admixture and cement composition - Google Patents

Description

注：ＮＤは検出下限以下であることを示す。
【００３７】
実験例２
セメント組成物100部中、セメント混和材を25部使用し、セメント混和材中のスラグＤとγ-2CaO・SiO₂の配合割合を表２に示すように変えたこと以外は実験例１と同様に行った。結果を表２に併記する。
【００３８】
【表２】

注：ＮＤは検出下限以下であることを示す。
【００３９】
実験例３
スラグＤ50部とγ-2CaO・SiO₂の50部からなるセメント混和材を使用し、セメントの種類を表３に示すように変えたこと以外は実験例１と同様に行った。結果を表３に併記する。
【００４０】
＜使用材料＞
セメントβ ：市販の高炉セメントＢ種
セメントγ ：市販の高炉セメントＣ種
【００４１】
【表３】

注：ＮＤは検出下限以下であることを示す。
【００４２】
実験例４
γ-2CaO・SiO₂の粗粉を粉砕し、ブレーン値が異なるγ-2CaO・SiO₂微粉末を作製して高炉徐冷スラグＤと混合し、さらに、セメント100部と混合して調製した点以外は実験例No.1-5と同様に行った。結果を表４に併記する。
【００４３】
【表４】

【００４４】
【発明の効果】
本発明のセメント混和材又は本発明のセメント組成物を使用することにより、セメントに含まれる有害重金属、特に六価クロムの溶出量を低減できる。また、流動性保持性能及び中性化抵抗性に優れるセメント組成物が得られるなどの効果を奏するため、土木・建築業界におけるコンクリート構造物に適する。[0001]
BACKGROUND OF THE INVENTION
The present invention mainly relates to a cement admixture and a cement composition used in the civil engineering and construction industries. In the present invention, “parts” and “%” are based on mass unless otherwise specified.
[0002]
[Prior art and its problems]
From the viewpoint of environmental issues, environmental standards have also been established for hexavalent chromium that adversely affects the human body (Environment Agency Notification No. 46, etc.). On the other hand, the cementitious material contains a small amount of chromium. Today, there are rare cases of cement with relatively high chromium content due to the increased frequency of waste disposal in cement production.
[0003]
Also, the elution amount of hexavalent chromium varies greatly depending on the method of use of the cementitious material, but the amount of hexavalent chromium that exceeds the environmental standard (0.05 mg / l) does not elute from ordinary hardened cement, In the case of concrete that has not yet solidified, there is a concern that hexavalent chromium exceeding the environmental standards may be eluted.
[0004]
However, the current situation is that no drastic measures have been taken with regard to the harmful heavy metals of concrete that have not yet solidified. A method for reducing harmful heavy metals such as hexavalent chromium with a reducing agent or an adsorbent has been proposed. However, these materials are too expensive to be used in the field of cement and concrete, and the actual situation is that they are rarely used.
[0005]
In recent years, the durability of concrete has been greatly improved, and the demand for improving the durability of concrete has increased. The deterioration factors of concrete include neutralization and salt damage.
[0006]
However, these are contradictory performance requirements. This is because salt damage is more susceptible as the amount of calcium hydroxide in the concrete increases. On the other hand, the neutralization is more susceptible to the smaller the amount of calcium hydroxide produced.
[0007]
In order to obtain concrete that is not easily affected by salt damage, a large amount of latent hydraulic substances such as blast furnace slag, fly ash, and silica fume are mixed to consume calcium hydroxide generated from cement hydration, and water. It is effective to use concrete with a small amount of calcium oxide. For example, using a commercially available blast furnace cement is the simplest method, and it is possible to take some measures even in the present situation.
[0008]
On the other hand, neutralization is a phenomenon caused by calcium hydroxide reacting with carbon dioxide in the atmosphere and being carbonated. Therefore, it is said that concrete having a smaller amount of calcium hydroxide is more susceptible to influence, and a material having excellent chloride penetration resistance such as blast furnace cement is likely to be neutralized. Today, there is a strong demand for the development of technology that effectively increases neutralization resistance without affecting chloride penetration resistance.
[0009]
In addition, the fluidity of concrete is extremely important because it is closely related to the occurrence of construction defects. It is necessary to hold it sideways from the raw plant, transport it to the construction site, and maintain fluidity for a certain period of time. However, in the case of being involved in some trouble or traffic jam at the site, the elapsed time greatly exceeds the predetermined time, and the hardening of the concrete has progressed, and the fluidity sometimes falls outside the predetermined standard.
[0010]
In such a case, there is no method other than performing a so-called refluidization treatment in which a high-performance AE water reducing agent or the like is added to concrete and fluidized again. This refluidization treatment has a problem that only a skilled person can perform it, and in order to prevent such a decrease in fluidity, a method for maintaining fluidity for a long time has been demanded.
[0011]
As described above, the present inventors have result of repeated extensive studies, by using the cement admixture comprising a slowly cooled blast furnace slag powder and γ -2CaO · SiO _2, elution reduction of toxic metals, slump It was found that the loss was reduced and the neutralization resistance was increased, and the present invention was completed.
[0012]
[Means for Solving the Problems]
That is, the present invention is a cement admixture containing 20 to 80 parts of blast furnace slow-cooled slag powder and γ-2CaO · SiO ₂ in 100 parts of cement admixture, and non-sulfate sulfur of blast furnace slow-cooled slag. The cement admixture is characterized by having a content of 0.5% or more, and the vitrification rate of the blast furnace annealed slag is 30% or less. And a cement composition containing the cement admixture, wherein the cement is a blast furnace cement.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail.
[0014]
The blast furnace slow-cooled slag used in the present invention is a blast furnace slag that has been cooled and crystallized.
[0015]
The components of blast furnace slow-cooled slag have the same composition as granulated blast furnace slag. Specifically, SiO ₂ , CaO, Al ₂ O ₃ , MgO, etc. are the main chemical components, and in addition, TiO ₂ , MnO, Na ₂ O, S, P ₂ O ₅ , Fe ₂ O _{3 and the} like. In addition, as a compound, the main component is so-called melilite, which is a mixed crystal of gelenite 2CaO · Al ₂ O ₃ · SiO ₂ and akermanite 2CaO · MgO · 2SiO ₂ , other than that, dicalcium silicate 2CaO · SiO ₂ , and lanknite 3CaO · 2SiO _2, calcium silicates, such as wollastonite CaO · SiO _2, Merubinaito 3CaO · MgO · 2SiO _2, calcium magnesium silicate, such as Monte celite CaO · MgO · SiO _2, anorthite _{CaO · Al 2 O 3 · 2SiO} 2, Includes leucite (K ₂ O, Na ₂ O) / Al ₂ O ₃ / SiO ₂ , spinel MgO / Al ₂ O ₃ , magnetite Fe ₃ O ₄ , and sulfides such as calcium sulfide CaS and iron sulfide FeS There is a case.
[0016]
In the present invention, among the blast furnace slow-cooled slag, fine powder of blast furnace slow-cooled slag obtained by pulverizing one containing sulfur present as non-sulfate sulfur (hereinafter simply referred to as non-sulfate sulfur) is used. The content of non-sulfate sulfur is not particularly limited, but is preferably 0.5% or more, more preferably 0.7% or more, and most preferably 0.9% or more. If the non-sulfuric sulfur is less than 0.5%, the effects of the present invention, that is, the fluidity retention performance and the hexavalent chromium reduction performance cannot be sufficiently obtained.
[0017]
The amount of non-sulfuric sulfur is determined by quantifying the amount of total sulfur, the amount of elemental sulfur, the amount of sulfide sulfur, the amount of thiosulfuric sulfur, and the amount of sulfuric sulfur (sulfur trioxide). The method for quantifying sulfur in different states can be obtained by the method of Yamaguchi and Ono. This is described in detail in a paper entitled “Analysis of Sulfur State in Blast Furnace Slag” (Naoji Yamaguchi, Shogo Ono: Steel Research, No. 301, pp. 37-40, 1980). Further, the amount of sulfate sulfur (sulfur trioxide) and the amount of sulfide sulfur can also be obtained by the method defined in JIS R 5202.
[0018]
The vitrification rate of the blast furnace slow cooling slag used in the present invention is preferably 30% or less, and more preferably 10% or less. If the vitrification rate exceeds 30%, sufficient fluidity retention performance and hexavalent chromium reduction performance may not be obtained.
[0019]
The vitrification rate (X) referred to in the present invention is determined as X (%) = (1−S / S ₀ ) × 100. Here, S is the main crystalline compound in the slow-cooled slag obtained by powder X-ray diffractometry (mixed crystal of gelenite 2CaO · Al ₂ O ₃ · SiO ₂ and akermanite 2CaO · MgO · 2SiO ₂ ). The area of the main peak, S ₀ represents the area of the main peak of melilite after the slow cooling slag was heated at 1,000 ° C. for 3 hours and then cooled at a cooling rate of 5 ° C./min.
[0020]
Blaine specific surface area of the slowly cooled blast furnace slag is not particularly limited, and more preferably from ^{3,000cm 2 / g~8,000cm 2 / g,} 4,000cm 2 / g~6,000cm 2 / g being most preferred. When the specific surface area of the brane is less than 3,000 cm ² / g, the effect of the present invention, that is, the hexavalent chromium reduction performance may not be sufficiently obtained. In addition, pulverization to exceed 8,000 cm ² / g is uneconomical because the pulverization power increases, and the blast furnace slow cooling slag tends to be weathered, and the quality tends to deteriorate over time. is there.
[0021]
Among the compounds represented by the chemical formula 2CaO · SiO ₂ , γ-2CaO · SiO ₂ used in the present invention is known as a low-temperature phase, and α-2CaO · SiO ₂ and β-2CaO · It is different from SiO ₂ . These are both 2CaO · SiO ₂ and have the same chemical composition, but their crystal structures are different. 2CaO · SiO ₂ present in the cement clinker is β-2CaO · SiO ₂ and does not contain γ-2CaO · SiO ₂ . β-2CaO · SiO ₂ has hydraulic properties, but does not exhibit neutralization resistance like γ-2CaO · SiO ₂ of the present invention.
[0022]
The method for industrially producing γ-2CaO · SiO ₂ of the present invention is not particularly limited, but in general, (1) a calcium source such as quick lime, slaked lime, and / or calcium carbonate as a CaO source, and (2) Examples thereof include a method of mixing and heat-treating two kinds of aluminum sources such as aluminum oxide, aluminum hydroxide, and / or bauxite.
[0023]
The temperature of the heat treatment is not particularly limited, and may vary depending on the raw materials used. Usually, it may be performed in a range of about 850 ° C. to 1600 ° C., and about 1,000 ° C. to 1,500 ° C. is preferable from the viewpoint of heat treatment efficiency.
[0024]
Blaine specific surface area of γ-2CaO · SiO ₂ is preferably ^{3,000~8,000cm 2 / g, 4,000~6,000cm 2 /} g is more preferable. If the Blaine specific surface area is less than 3,000 cm ² / g, neutralization resistance may not be sufficiently obtained.
[0025]
When industrially producing γ-2CaO · SiO ₂ of the present invention, the presence of impurities is not particularly limited, and is not particularly problematic as long as the object of the present invention is not substantially inhibited. Specific examples thereof include Al ₂ O ₃ , MgO, TiO ₂ , MnO, Na ₂ O, S, P ₂ O ₅ , and Fe ₂ O ₃ .
[0026]
The compound coexist, tri calcium silicate 3CaO · SiO _2, rankinite night 3CaO · 2SiO _2, wollastonite calcium silicates, such as CaO · SiO _2, Meruvi night 3CaO · MgO · 2SiO _2, Akerumanaito 2CaO · MgO · 2SiO ₂ , and calcium magnesium silicates such as Monticellite CaO ・ MgO ・ SiO ₂ , Gerenite 2CaO ・ Al ₂ O ₃・ SiO ₂ and calcium aluminosilicates such as Anorthite CaO ・ Al ₂ O ₃・ 2SiO ₂ , Akermanite and Gelenite mixed Crystalline melilite, magnesium silicates such as MgO · SiO ₂ and 2MgO · SiO ₂ , free lime, free magnesia, calcium ferrite 2CaO · Fe ₂ O ₃ , calcium aluminoferrite 4CaO · Al ₂ O ₃ · Fe ₂ O ₃ , Liu site _{(K 2 O, Na 2 O} ) · Al 2 O 3 · SiO 2, spinel MgO · Al ₂ O _3, as well, may include magnetite Fe ₃ O ₄ That.
[0027]
The amount of the cement admixture of the present invention is not particularly limited, and is preferably 5 to 50 parts, more preferably 10 to 30 parts, in 100 parts of a cement composition composed of cement and cement admixture.
[0028]
The blending ratio of the slow-cooled slag and γ-2CaO · SiO ₂ in the cement admixture of the present invention is not particularly limited, but is usually preferably 20 to 80 parts each in 100 parts of the cement admixture, 30 to 70 parts is more preferred. If the slow cooling slag is less than 20 parts or γ-2CaO · SiO ₂ exceeds 80 parts, the effect of reducing harmful heavy metals and fluidity retention performance may not be sufficiently obtained. On the other hand, if the slow cooling slag exceeds 80 parts or γ-2CaO · SiO ₂ is less than 20 parts, sufficient neutralization resistance may not be obtained.
[0029]
In the present invention, in addition to slow-cooled slag and γ-2CaO · SiO ₂ , conventionally known harmful heavy metal reducing agents can be used in combination as long as the object of the present invention is not substantially inhibited. Specific examples thereof are layered compounds typified by montmorillonite and kaolinite, so-called bentonites, zeolites typified by clinoptilolite and mordenite, sepiolite, apatite, and phosphoric acids such as zirconium phosphate. Salts, sulfur compounds such as antimony trioxide and antimony pentoxide, hydrotalcites, activated carbon, polysulfides, sulfides, thiosulfates, sulfites, amalgam, ferrous sulfate, ferrous chloride Iron compounds such as cellulose, water-soluble polymers such as polyvinyl alcohol, chitosan, dialkyldithiocarbamic acids, quinoline compounds, polyamines, saccharides, etc., and one or more of these harmful heavy metal reducing agents Can be used in combination.
[0030]
Although the cement used in the present invention is not particularly limited, it is preferable to use a cement containing Portland cement. For example, various portland cements such as normal, early strength, super early strength, low heat, or moderate heat, and blast furnaces for these portland cements are used. Examples include various mixed cements obtained by mixing granulated slag, fly ash, or silica, or limestone filler cement obtained by mixing limestone powder with Portland cement.
[0031]
In the present invention, in addition to cement, the present admixture, aggregates such as sand and gravel, water reducing agent, AE water reducing agent, high performance water reducing agent, AE high performance water reducing agent, ground granulated blast furnace slag, blast furnace slow cooling slag Admixtures such as fine powder, fine limestone powder, fly ash, and silica fume, expansion material, rapid hardening material, antifoaming agent, thickener, rust preventive agent, antifreeze agent, shrinkage reducing agent, polymer, setting agent, bentonite You may use 1 type (s) or 2 or more types of clay minerals, such as hydrotalcite, etc. within the range which does not inhibit the objective of this invention.
[0032]
【Example】
Hereinafter, further description will be given based on experimental examples of the present invention.
[0033]
Experimental example 1
Various slags shown in Table 1 and γ-2CaO · SiO ₂ were mixed at a mass ratio of 1: 1 to prepare a cement admixture. Mix the cement admixture in the proportion shown in Table 1 with respect to 100 parts of cement α, and prepare a mortar with a water / cement composition ratio = 50% and a cement composition / sand ratio of 1/3. The amount of hexavalent chromium to be eluted, fluidity retention performance (evaluated as flow loss), compressive strength, and neutralization depth were measured. For comparison, the same procedure was performed for the case of using limestone fine powder. The results are also shown in Table 1.
[0034]
<Materials used>
Cement α: Commercially available ordinary Portland cement slag A: Blast furnace annealing slag, Blaine specific surface area 3,000 cm ² / g, Vitrification rate 5%, Specific gravity 3.00, Non-sulfate sulfur 0.9%
Slag B: Blast furnace slow-cooled slag, Blaine specific surface area 4,000cm ² / g, Vitrification rate 5%, Specific gravity 3.00, Non-sulfate sulfur 0.9%
Slag C: Blast furnace annealing slag, Blaine specific surface area 5,000cm ² / g, Vitrification rate 5%, Specific gravity 3.00, Non-sulfate sulfur 0.9%
Slag D: Blast furnace annealing slag, Blaine specific surface area 6,000cm ² / g, Vitrification rate 5%, Specific gravity 3.00, Non-sulfate sulfur 0.9%
Slag E: Blast furnace annealing slag, Blaine specific surface area 8,000cm ² / g, Vitrification rate 5%, Specific gravity 3.00, Non-sulfate sulfur 0.9%
Slag F: Blast furnace slow-cooled slag and blast furnace granulated slag D were dipped in water and aged to make non-sulfuric sulfur 0.7%. Blaine specific surface area 6,000cm ² / g, vitrification rate 5%, specific gravity 3.00.
Slag G: Blast furnace slow-cooled slag and blast furnace granulated slag D are dipped in water and aged to make non-sulfate sulfur 0.5%. Blaine specific surface area 6,000cm ² / g, vitrification rate 5%, specific gravity 3.00.
Slag H: Blast furnace slow cooling slag, Blaine specific surface area 6,000cm ² / g, Vitrification rate 10%, Specific gravity 2.97, Non-sulfate sulfur 0.7%
Slag I: Blast furnace annealing slag, Blaine specific surface area 6,000cm ² / g, Vitrification rate 30%, Specific gravity 2.94, Non-sulfate sulfur 0.5%
Slag J: Granulated blast furnace slag, Blaine specific surface area 6,000cm ² / g, Vitrification rate 95%, Specific gravity 2.90, Non-sulfate sulfur 0.6%
γ-2CaO · SiO ₂ : 2 moles of reagent grade 1 calcium carbonate and 1 mole of reagent grade 1 silicon dioxide were mixed and ground, then fired at 1450 ° C for 3 hours in an electric furnace, taken out of the furnace and naturally It was cooled and then synthesized. Dusting was performed during natural cooling, and the powder was pulverized to a specific surface area of 1,800 cm ² / g. This was further pulverized to a Blaine specific surface area of 4,000 cm ² / g.
Limestone fine powder (LSP): A limestone from the Aomi mine ground to a specific surface area of 6,000 cm ² / g. Specific gravity 2.71
Sand: JIS standard sand [0035]
<Measurement method>
Hexavalent chromium concentration: 50 g of mortar that has not yet solidified immediately after kneading is placed in 500 cc of pure water, stirred, and solid-liquid separated, and the hexavalent chromium concentration in the liquid phase is measured by ICP emission spectroscopy in accordance with JIS K 0102 did.
Flow loss: The flow value was measured in accordance with JIS R 5201, and the difference between the flow value immediately after kneading and 120 minutes after was evaluated as flow loss.
Compressive strength: A 4 × 4 × 16 cm cured body was prepared and measured on the age of 28 days according to JIS R 5201.
Neutralization depth: 4 × 4 × 16cm hardened body, cured in 20 ° C water until 14 days of age, then at room temperature 30 ° C, carbon dioxide concentration 5%, relative humidity 60% Neutralization resistance was confirmed by measuring the neutralization depth by cutting the mortar and spraying a phenolphthalein alcohol solution on the cross section after 8 weeks from the start of neutralization.
[0036]
[Table 1]

Note: ND indicates below the lower detection limit.
[0037]
Experimental example 2
Same as Experimental Example 1 except that 25 parts of cement admixture was used in 100 parts of the cement composition, and the blending ratio of slag D and γ-2CaO · SiO ₂ in the cement admixture was changed as shown in Table 2. Went to. The results are also shown in Table 2.
[0038]
[Table 2]

Note: ND indicates below the lower detection limit.
[0039]
Experimental example 3
The same procedure as in Experimental Example 1 was conducted except that a cement admixture consisting of 50 parts of slag D and 50 parts of γ-2CaO · SiO ₂ was used and the type of cement was changed as shown in Table 3. The results are also shown in Table 3.
[0040]
<Materials used>
Cement β: Commercial blast furnace cement type B cement γ: Commercial blast furnace cement type C
[Table 3]

Note: ND indicates below the lower detection limit.
[0042]
Experimental Example 4
γ-2CaO · SiO ₂ coarse powder was pulverized, γ-2CaO · SiO ₂ fine powders with different brane values were prepared and mixed with blast furnace slow-cooled slag D, and further mixed with 100 parts of cement Except for this, the same procedure as in Experimental Example No. 1-5 was performed. The results are also shown in Table 4.
[0043]
[Table 4]

[0044]
【The invention's effect】
By using the cement admixture of the present invention or the cement composition of the present invention, the elution amount of harmful heavy metals, particularly hexavalent chromium, contained in the cement can be reduced. In addition, since the cement composition having excellent fluidity retention performance and neutralization resistance can be obtained, it is suitable for a concrete structure in the civil engineering and construction industries.

Claims (5)

A cement admixture comprising 20 to 80 parts of blast furnace slow-cooled slag powder and γ-2CaO · SiO ₂ in 100 parts of cement admixture. The cement admixture according to claim 1, wherein the content of non-sulfate sulfur in the blast furnace chilled slag is 0.5% or more .   The cement admixture according to claim 1 or 2, wherein the vitrification rate of the blast furnace slow cooling slag is 30% or less.   A cement composition comprising cement and the cement admixture according to claim 1.   The cement composition according to claim 4, wherein the cement is a blast furnace cement.