JP2019142749A - Cement composition and method for producing cement composition - Google Patents

Abstract

To provide a cement composition having an appropriate strength development property and effectively suppressing heat of hydration.SOLUTION: A cement composition characterized in that the mineral composition by X-ray diffraction-Rietveld analysis has a CS content of 50 mass% to 65 mass%, a CS content of 10 mass% to 25 mass%, a CA content of 6 mass% to 11 mass%, and a CAF content of 9 mass% to 12 mass%, wherein the amount of KO solid-solved in CA is 0.3 mass% or less. Preferably, the specific surface area of Blaine is 3100-3500 cm/g, and it is preferable to include a step of mixing gypsum and a small amount of mixed components into the clinker obtained in the step of producing the cement clinker, and pulverizing the resulting mixture.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a cement composition in which heat of hydration is suppressed even when a large amount of industrial waste, general waste, construction generated soil or the like is used as a raw material, and cement composition in which heat of hydration is suppressed It relates to the manufacturing method.

In recent years, with the increasing acceptance of various wastes and by-products in the cement industry, the mineral composition of Portland cement tends to have an increased amount of interstitial phase (aluminate phase: C ₃ A + ferrite phase: C ₄ AF) than before. It is in. In particular, since an increase in the amount of C ₃ A directly leads to an increase in the amount of heat of hydration of the cement, very strict cement quality control is required.

  JIS R 5210 “Portland cement” is known as an official standard for the quality of ordinary portland cement, which is the most common cement. Although no standard for heat of hydration has been established here, in February 1990, the former Ministry of Construction issued a notice about “ordinary Portland cement used for concrete structures”. In this notification, regarding the heat of hydration of ordinary Portland cement, the management target value of 350 J / g or less at the age of 7 days and 400 J / g or less at the age of 28 days is shown. Therefore, it has been strongly demanded to control the heat of hydration of ordinary portland cement, which is a general-purpose cement.

Against this background, technological development is proceeding regarding a method for suppressing heat of hydration of ordinary Portland cement using a large amount of waste. For example, Patent Document 1 discloses a method of reducing the heat of hydration of a cement composition in which the raw material unit of the cement clinker or the cooling rate is adjusted based on the value of the lattice volume of the crystal lattice of the alite phase. A method for reducing the heat of hydration of a cement composition in which the raw material unit of the cement clinker is adjusted based on the color tone b value of the cement composition is disclosed in Patent Document 3, wherein the Sr content is 0.02 to 0.04 mass. Is a cement composition in which a cement admixture composed of a low exothermic mineral phase such as C ₂ S or C ₂ AS obtained by using a large amount of waste is mixed in Patent Documents 4 and 5. Things are disclosed.

JP 2011-20890 A JP 2011-132045 A JP 2011-140424 A JP 2004-2155 A JP 2008-222464 A

  However, the methods described in Patent Documents 1 to 3 do not have a sufficient effect of suppressing the heat of hydration of the cement composition. In the methods described in Patent Documents 4 and 5, a special cement admixture is used. It must be manufactured separately and is not realistic.

  The cement composition causes a hydration reaction upon contact with water, and develops the strength of the hardened cement body by forming a hydrate. Since the heat of reaction generated in this hydration reaction is the heat of hydration, generally a cement composition with a quicker strength development has a higher hydration heat value. That is, the cement composition in which the heat of hydration is suppressed has a problem that strength development tends to be low.

  Accordingly, an object of the present invention is to provide a cement composition that can sufficiently suppress the heat of hydration even when a large amount of various wastes are used and has an appropriate strength development property without using a special cement admixture. Is to provide.

Therefore, the present inventor has made various studies, and by adjusting the amount of K ₂ O dissolved in C ₃ A in the cement clinker, the heat of hydration is sufficiently suppressed even when the amount of interstitial phase increases. It has been found that a composition can be obtained, and that such a cement composition has appropriate strength development properties, and the present invention has been completed.

That is, according to the present invention, the mineral composition according to the X-ray diffraction-Riet belt analysis method has a C ₃ S amount of 50% by mass to 65% by mass, a C ₂ S amount of 10% by mass to 25% by mass, and a C ₃ A amount. 6 wt% to 11 _{wt%, cement C} 4 AF amount a 9 wt% to 12 wt%, _{K 2} O amount which forms a solid solution in _{C 3} a is equal to or less than 0.3 wt% A composition is provided.

In addition, the present invention is obtained in steps (I) and (I) of producing a cement clinker so that the amount of K ₂ O dissolved in C ₃ A in the cement clinker is 0.3% by mass or less. The present invention provides a method for producing the above cement composition, which comprises the step (II) of mixing and crushing gypsum and a small amount of mixed components into the cement clinker.

  The present invention does not require the use of a special chemical component as a cement clinker raw material, and only uses a cement clinker obtained by adding an easy operation to the production process. A cement composition with suppressed heat of hydration can be provided.

Cement compositions obtained in Examples and Comparative Examples, is a graph showing the relationship between the K _{2 O} content and 7 days ages of hydration heat of solid solution C 3 _A. Cement compositions obtained in Examples and Comparative Examples, is a graph showing the relationship between the K _{2 O} content and 28 ages of hydration heat of solid solution C 3 _A.

Hereinafter, the present invention will be described in detail.
The cement composition of the present invention has a C ₃ S amount of 50 mass% to 65 mass% and a C ₂ S amount of 50% by mass to 65% by mass from the viewpoint of ensuring that the mineral composition by the X-ray diffraction-Riet belt analysis method has an appropriate strength development. 10% by mass to 25% by mass, 6% by mass to 11% by mass of C ₃ A, and 9% by mass to 12% by mass of C ₄ AF. That is, the cement composition of the present invention has a mineral composition classified into ordinary Portland cement and early-strength Portland cement, based on the type of Portland cement specified in the above-mentioned JIS R 5210 “Portland cement”.
In addition, as the amount of the cement clinker mineral in the cement clinker or the cement composition, a value calculated by the Borg equation using the quantitative analysis result of the chemical component is generally used. Regarding the amount of C ₃ A and C ₄ AF that cannot be ignored, the actual amount of mineral (for example, the measured value by the point counting method, or the measured value of each mineral phase separated by the combination of selective dissolution and heavy liquid separation). Since there is a large discrepancy from the value calculated from the Borg equation, the mineral composition (mass%) of the cement clinker or cement composition in the present invention is closer to the actual mineral amount unless otherwise noted. Refers to the value obtained from.

The cement composition of the present invention is characterized in that the amount of K ₂ O dissolved in C ₃ A is 0.3% by mass or less.
C ₃ A is the CaO in the cement clinker that has been acting as a liquid phase (melt) until the cement clinker sufficiently fired at a firing temperature of 1300 ° C. or higher is quenched at the outlet of the cement kiln. Whether components such as Al ₂ O ₃ , Fe ₂ O ₃ , MgO, alkali (K ₂ O, Na ₂ O), SO ₃ precipitate as small crystals in the gaps between large crystals of C ₃ S and C ₂ S It is one of the cement clinker minerals that form a so-called interstitial phase that exists as an amorphous material, and has the highest hydration reactivity among cement clinker minerals.

The amount of C ₃ A in the cement clinker is affected by the amount of Al ₂ O ₃ and Fe ₂ O ₃ in the cement clinker raw material and the cooling rate in the cement clinker manufacturing process, and a large amount of waste is used as the cement clinker raw material. Under the present circumstances, since the amount of Al ₂ O ₃ in the cement clinker raw material tends to be excessive, cement clinker containing 9.0% by mass or more of C ₃ A has become common.

The hydration reactivity of C ₃ A is very intense, and when C ₃ A and water come into contact with each other and water is hydrated, a stiffening (instantaneous setting) occurs immediately. Mixed to suppress the hydration rate of C ₃ A. However, even if such a C ₃ A-gypsum hydration reaction system is constructed, C ₃ A remains the most hydrated reactive cement clinker mineral, and the heat of hydration of the cement composition remains unchanged. In order to suppress this, it is necessary to control the hydration reactivity of C ₃ A.

K ₂ O is, a minor component which is usually contained in the cement composition, supra JIS R 5210 in "portland cement", the total alkali content as the total amount of _{Na 2 O Na 2 O eq (} = Na 2 O (Mass%) + 0.658 × K ₂ O (mass%) is regulated to 0.75 mass% or less, and low alkaline Portland cement is regulated to 0.60 mass% or less.

_{K 2} O in the cement _{clinker, K 2 SO 4, Na 2} SO 4 · 3K 2 SO 4, or present as a sulfate salt such as 2CaSO ₄ · _K 2 SO _4, there are a solid solution in the cement clinker minerals . Then, C 3 _A is one of the cement clinker minerals dissolved much K _{2 O,} the upper limit of the solid solution amount exceeds 1.0 mass%.

The present inventor has and K _{2 O} amount of solid solution in the C _{3 A,} that there is a correlation and hydration of the cement composition fever, in particular, the larger the K _{2 O} solid solution amount of C 3 _A, It has been found that the heat of hydration of the cement composition is increased. The cement composition of the present invention controls the amount of K ₂ O dissolved in C ₃ A so as to be a specific value or less, thereby maintaining the strength development property of the cured cement composition while maintaining the heat of hydration. Can be reduced.
Here, the amount of K ₂ O dissolved in C ₃ A is a value obtained by energy dispersive X-ray spectroscopy (hereinafter referred to as “SEM-EDS”) in a scanning electron microscope. About C ₃ A in the above different cement clinker grains, it was obtained as an average value of values measured in total of 15 or more points, and the ratio (mass%) to the total of 100 mass% of the chemical components of the C ₃ A particles Indicates.

The amount of K ₂ O dissolved in C ₃ A in the cement composition of the present invention is 0.3% by mass or less, preferably 0.25% by mass or less, more preferably 0.2% by mass or less. It is. The lower limit of _{K 2} O amount of solid solution in the _{C 3} A, there is no particular limitation. When the amount of K ₂ O dissolved in C ₃ A in the cement composition exceeds 0.3% by mass, the effect of suppressing heat of hydration is reduced.

Ensuring an appropriate range of the amount of K ₂ O dissolved in C ₃ A can be achieved by adjusting the SO ₃ content of the cement clinker. That is, as described above, most of K ₂ O in the cement clinker exists as a sulfate or a solid solution in C ₃ A, but preferentially takes the form of sulfate. Thus, for K _{2 O} content in the cement clinker raw material, it is possible to adjust the K _{2 O} content of the sulfate by controlling the mixing amount of S, as a result, forms a solid solution in C 3 _A It becomes possible to adjust the amount of K ₂ O.

  S contained in the cement clinker is derived from S brought into the cement kiln as a cement clinker raw material or brought into the cement kiln as a contaminant component in the fuel for burning the cement clinker.

The S derived from the cement clinker raw material is one that contains natural raw materials or various wastes that have been recycled, or has been intentionally charged with an S source such as gypsum into the cement kiln.
Specifically, gypsum, waste gypsum board, etc. can be added in the raw material process, and can be charged from the kiln bottom of the cement kiln as a normal cement clinker raw material. In this method, the clinker firing zone in the cement kiln is used. May cause a decrease in the temperature of the cement clinker, resulting in an increase in the amount of free lime in the cement clinker and a draft failure due to volatilization and concentration of S, which may result in a deterioration in the quality of the cement clinker and an obstacle to the stable operation of the cement kiln. There is.
Therefore, when S is brought in as a cement clinker raw material, for example, as described in JP 2011-26174 A, JP 2013-177314 A, etc., gypsum and waste gypsum board from the kiln front of the cement kiln Etc. are preferably blown.

When S is brought in as a burning fuel for cement clinker, there is a method of using a fuel having a high SO ₃ content such as oil coke or a coal having a relatively high S content such as subbituminous coal. However, in recent fuel situations, fuels with a high SO ₃ content such as oil coke are becoming increasingly difficult to obtain.

The SO ₃ content of the cement clinker used in the cement composition of the present invention is preferably 0.18% by mass or more, more preferably 0.2% by mass or more, and particularly preferably 0.22% by mass or more. When the SO ₃ content of the cement clinker is within the above range, the amount of K ₂ O dissolved in C ₃ A becomes the above appropriate range, and the heat of hydration of the cement composition can be sufficiently suppressed. . Here, the SO ₃ content of the cement clinker is a content ratio (% by mass) with respect to the total mass (100% by mass) of the cement clinker, and JIS R 5202 “Method of chemical analysis of Portland cement” or JIS R 5204 “ It can be measured according to the “X-ray fluorescence analysis method”.

Furthermore, the cement composition of the present invention, from the viewpoint of securing adequate strength development, Blaine specific surface area as defined in JIS R 5201 "Physical testing methods for cement" is preferably 3100cm ² / g~3500cm ² / g, more preferably 3150cm ² / g~3400cm ² / g, particularly preferably 3200cm ² / g~3300cm ² / g.

Moreover, it is preferable that the cement composition of this invention contains gypsum from a viewpoint which suppresses the heat | fever of hydration, and a viewpoint which ensures appropriate intensity | strength expression. The proportion of gypsum in 100% by mass of the cement composition is 1.2% by mass or more, preferably 1.3% by mass to 5% by mass, more preferably 1.4% by mass to 4% by mass in terms of SO _3. . When the amount of gypsum is less than 1.2% by mass, the cement composition of the present invention may have high heat of hydration or low strength development.
The amount of SO ₃ in the cement composition is determined in accordance with JIS R 5202 “Cement chemical analysis method” or JIS R 5204 “Cement fluorescent X-ray analysis method”. by subtracting the the SO ₃ content derived from cement clinker cement composition in consideration of the intensity for SO ₃ content of the cement clinker, it is possible to obtain the SO ₃ content derived from gypsum.
In addition, the amount of gypsum can be directly calculated | required more simply from the X-ray diffraction-Riet belt analysis regarding a cement composition.

Examples of the gypsum include dihydrate gypsum, α-type or β-type hemihydrate gypsum, and anhydrous gypsum. These can be used alone or in combination of two or more. Proportion of hemihydrate gypsum to the total amount 100 mass% of gypsum and hemihydrate gypsum in the cement composition of the present invention, SO ₃ terms of the amount of 30 mass% or more, preferably 50 mass% or more, more preferably 70 It is at least mass%. The fluidity | liquidity of the cement composition of this invention can be improved as this ratio is 30 mass% or more.
The quantification of dihydrate gypsum and hemihydrate gypsum can be performed by, for example, a method described in JP-A-6-242035 in addition to the above X-ray diffraction-Riet belt analysis.

  Furthermore, the cement composition of the present invention contains a small amount of mixed components (blast furnace slag, siliceous mixed material, fly ash type I or type II, calcium carbonate) specified in the above-mentioned JIS R 5210 “Portland cement”. You may contain to 5 mass% in 100 mass%.

Next, the manufacturing method of the cement composition of this invention is demonstrated.
The cement composition of the present invention includes, for example, a step (I) and a step (I) of producing a cement clinker so that the amount of K ₂ O dissolved in C ₃ A in the cement clinker is 0.3% by mass or less. The cement clinker obtained in (1) can be produced by a method comprising a step (II) of mixing and crushing gypsum and a small amount of mixed components.
More specifically, in the step (I), the mineral composition of the cement composition has a C ₃ S amount of 50% by mass to 65% by mass, a C ₂ S amount of 10% by mass to 25% by mass, and C ₃ A. Natural raw materials, industrial wastes, general wastes, so as to be cement clinker having an appropriate mineral composition such that the amount is 6% by mass to 11% by mass and the amount of C ₄ AF is 9% by mass to 12% by mass. When preparing the cement clinker by adjusting the raw material basic units of one or two or more kinds of raw materials selected from the group consisting of the soil generated from construction and producing the cement clinker, The amount of S in the raw material blown from the front part of the kiln kiln, and further the amount of S contained in the firing fuel are adjusted, so that K ₂ O dissolved in C ₃ A in the cement clinker obtained. The amount is 0.3% by mass or less Sea urchin, the production of cement clinker.

In the step (I), as raw materials used for the cement clinker preparation raw material, natural raw materials include limestone, meteorite, clay, gypsum, industrial waste as coal ash, waste gypsum board, iron sludge, copper tangled, blast furnace dust, Other sludges, sewage sludge, etc. as general waste, and construction waste soil.
Examples of the raw material blown from the front of the kiln kiln include high S raw materials such as gypsum and waste gypsum board. As described above, the amount of alkali sulfate can be adjusted by blowing gypsum or waste gypsum board from the front of the kiln.

The method of adjusting the amount of S so that the amount of K ₂ O dissolved in C ₃ A is 0.3% by mass or less adjusts the amount of S relative to the amount of K ₂ O in the cement clinker raw material. S contained in the cement kiln includes sulfur oxides that are exhausted and discharged outside the system. Therefore, by adjusting the balance of the amount fed into the cement kiln, K can be dissolved in C ₃ A. _It is difficult to control the amount of 2O.

A simple and practical method includes K ₂ O amount (K _C , mass%) in the cement clinker discharged from the cement kiln, K ₂ O amount (Ks, mass%) in alkali sulfate (water-soluble alkali), And the amount of C ₃ A in the cement clinker (CA, mass%) was measured, and the amount of K ₂ O that did not become alkali sulfate ((K _C -Ks), mass%) was all dissolved in C ₃ A. The K ₂ O solid solution amount (((K _C -Ks) / CA) × 100 (% by mass)) is calculated, and the blended raw material and the kiln pre-blown raw material are set so that the calculated value becomes a predetermined value. In addition, the type and / or amount of fuel used may be adjusted.
Here, the quantitative analysis of the amount of K ₂ O in the alkali sulfate contained in the cement clinker may be performed according to the Cement Association Standard Test Method JCAS I-04: 2004 “Analytical Method of Water-Soluble Components of Cement”.

  In the step (I), the target cement clinker can be obtained by firing with a kiln by an ordinary method using the raw material thus adjusted.

  In step (II), the cement clinker obtained in step (I) can be mixed with gypsum and a small amount of mixed components and pulverized by using a general-purpose cement pulverization method. And a method using a closed circuit mill composed of a machine and a classifier such as a separator.

  EXAMPLES The present invention will be specifically described below with reference to examples, but the present invention is not limited to these examples.

1. Cement composition:
Nine types of cement clinker are fired with NSP kiln, which is a raw material of cement clinker, which is mainly composed of limestone, clay, silica, iron, etc. Then, drained dihydrate gypsum was added to all cement clinker to obtain nine types of cement compositions having the chemical composition shown in Table 1. In the chemical composition in Table 1, “SO ₃ ” is a value including the amount of SO ₃ derived from the added gypsum.
The analysis of the chemical composition of the cement composition was in accordance with JIS R 5204 “Method for X-ray fluorescence analysis of cement”.

About all the obtained cement compositions, mineral composition (X-ray diffraction-Riet belt analysis), Blaine specific surface area (according to JIS R 5201 “Physical test method of cement”), free lime amount (standard test method JCAS I of Cement Association) −01: 1997 “Quantitative determination method of free calcium oxide”), alkali sulfate amount (JCAS I-04: 2004 “Analysis method of water-soluble components of cement”), and K ₂ O amount dissolved in C ₃ A (SEM-EDS) was measured.
The obtained results are shown in Table 1.

Moreover, about all the obtained cement compositions, heat of hydration (JIS R5203 "Method of measuring heat of hydration of cement (Method of heat of dissolution)") and mortar compressive strength (JIS R 5201 "Physical test of cement") Method ”compliant) was measured.
The obtained results are shown in Table 1.
A graph showing the relationship between the amount of K ₂ O dissolved in C ₃ A and the heat of hydration at 7 days of age is shown in FIG. 1, and the amount of K ₂ O dissolved in C ₃ A and water at the age of 28 days is shown in FIG. A graph showing the relationship between Japanese heat is shown in FIG.

1 and 2, the cement composition of the present invention in which the amount of K ₂ O dissolved in C ₃ A is 0.3% by mass or less is sufficient for both the 7-day age and the 28-day age. It can be seen that the heat of hydration is suppressed.
Furthermore, from Table 1, the mortar compressive strength of the cement composition of the present invention expresses appropriate strength at both the 7-day age and the 28-day age.

Claims (5)

The mineral composition according to the X-ray diffraction-Riet belt analysis method is such that the C ₃ S amount is 50 mass% to 65 mass%, the C ₂ S amount is 10 mass% to 25 mass%, and the C ₃ A amount is 6 mass% to 11 mass. %, The amount of C ₄ AF is 9% by mass to 12% by mass, and the amount of K ₂ O dissolved in C ₃ A is 0.3% by mass or less. Blaine specific surface area ^is 3100cm ² / g~3500cm 2 / g, cementitious composition of claim 1. Step (I) of producing a cement clinker so that the amount of K ₂ O dissolved in C ₃ A in the cement clinker is 0.3% by mass or less, and the cement clinker obtained in step (I) to gypsum The method for producing a cement composition according to claim 1, further comprising a step (II) of mixing and pulverizing a small amount of mixed components. Wherein step (I) is, _{K 2} O content in the cement clinker, _{K 2} O content in the alkali sulfate, and measures the _{C 3} A content in the cement clinker, _{K 2} O amount which forms a solid solution in _{C 3} A using the method of calculating the, K _{2 O} amount which forms a solid solution in C 3 _a to adjust the feed so that 0.3 wt% or less, the production method of the cement composition of claim 3.   The method for producing a cement composition according to claim 3 or 4, wherein the alkali sulfate amount in step (I) is adjusted by blowing gypsum or waste gypsum board from the front of the kiln.

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