JP2017149606A - Moderate heat fly-ash cement - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide moderate heat fly-ash cement having improved strength development without following rise of hydration heat evolution.SOLUTION: Moderate heat fly-ash cement comprises 65-75 pts. mass moderate heat portland cement, and 25-35 pts. mass fly ash. In the moderate heat fly-ash cement, the moderate heat portland cement is cement comprising gypsum, and moderate heat portland cement clinker containing 0.60-1.00 mass% SO.SELECTED DRAWING: None

Description

  The present invention relates to a medium heat fly ash cement with improved strength development.

Thermal cracks that occur in mass concrete such as dams can cause water leakage and corrosion of reinforcing bars. Therefore, in order to construct a structure having excellent durability and functionality, it is necessary to reduce temperature cracks as much as possible, and measures for reducing temperature cracks are important.
One of the countermeasures for reducing the temperature cracks in mass concrete is a method in which part of the cement is replaced with fly ash to reduce the hydration heat value of the cement, which is the cause of the concrete temperature rise. In recent years, medium-heated fly ash cement obtained by replacing 30% by mass of medium-heated Portland cement with fly ash has become the mainstream of cement used for dam concrete. In addition to reducing the hydration heat value, the cement has effects such as improving the workability of concrete and increasing long-term strength.

  Since the strength of concrete appears as a result of the hydration reaction of cement, the magnitude of the strength of the concrete and the magnitude of the hydration heat generation of the cement used in the concrete almost coincide. Therefore, if the hydration exotherm of the cement is suppressed too much, the strength development of the cement composition such as concrete is impaired. Therefore, the cement used for the mass concrete has a low hydration calorific value and an appropriate strength development. Compatibility is required.

  For example, in Non-Patent Document 1, when the substitution rate of fly ash increases to 50%, the adiabatic temperature rises as compared with 30%. Is reduced by 6.8 ° C., and it is reported that the compression strength ratio is comparable to the cement amount ratio at 91 days of age.

Hirama Akinobu et al .: Effect of fly ash replacement rate on strength and heat generation characteristics of dam concrete, Proceedings of the 64th Annual Conference of the Japan Society of Civil Engineers, pp. 437-438 (2009)

  However, the prior art does not intend to fundamentally improve the strength development in that the strength development is only required to be approximately the same as the substitution rate based on the fly ash substitution rate of cement.

  Therefore, an object of the present invention is to provide a moderately heated fly ash cement with improved strength development without increasing hydration exotherm.

Accordingly, as a result of intensive investigations on the method for improving the strength development of medium-heated fly ash cement, the present inventor used medium-heated Portland cement clinker having a specific content of SO _{3 in} the medium-heated fly ash cement. As a result, it was found that the moderately heated fly ash cement suppresses an increase in the hydration calorific value and increases the strength development, and the present invention has been completed.
That is, the present invention is a moderately heated fly ash cement having the following configuration and good strength development.

[1] Medium-heated fly ash cement composed of 65 to 75 parts by weight of medium-heated Portland cement and 25 to 35 parts by weight of fly ash, wherein the medium-heated Portland cement contains gypsum and SO ₃ of 0.60 to 1. Medium-heated fly ash cement comprising medium-heated Portland cement clinker containing 0.000% by mass.
However, the total amount of the medium-heated Portland cement and fly ash is 100 parts by weight, and the SO ₃ content (% by mass) is the content when the medium-heated Portland cement clinker is 100% by mass. is there.
[2] the 3CaO · SiO ₂ to moderate heat Portland cement clinker in a car (hereinafter abbreviated as _{"C 3} S".) The 42.5 to 49.0 wt%, and 3CaO · _Al 2 _{O 3} (hereinafter _{"C 3} A "is abbreviated as A).
However, the content (mass%) of the C ₃ S and C ₃ A is a content when the medium heat Portland cement clinker is 100 mass%, and is a value measured by an X-ray diffraction-Rietbelt method. .
[3] The above-mentioned [1] or [3], wherein the gypsum is a mixture of dihydrate gypsum and hemihydrate gypsum, and the mixture contains 1.8 to 2.7% by mass in terms of SO ₃ in moderately heated Portland cement. 2] Medium heat fly ash cement.
However, the content (mass%) of the gypsum (in terms of SO ₃ ) is the content when the medium heat Portland cement is 100 mass%.

The moderately hot fly ash cement of the present invention can improve strength development without increasing the hydration exotherm by using only the moderately hot Portland cement clinker containing a specific amount of SO ₃ .

As described above, the medium heat hot ash cement of the present invention is made of fly ash and medium heat Portland cement, and the medium heat Portland cement is made of gypsum and a medium heat Portland cement clinker containing a specific amount of SO ₃ .
Hereinafter, the present invention will be described in detail for medium-heated fly ash cement (medium-heated Portland cement clinker, gypsum, medium-heated Portland cement, and fly ash) and a method for producing medium-heated fly ash cement.

1. Medium-heated fly ash cement (1) Medium-heated Portland cement clinker The medium-heated Portland cement clinker in the medium-heated fly ash cement of the present invention contains 0.63 to 1.00% by mass of SO ₃ . If the content of SO ₃ is in the above range, strength development can be improved without increasing the hydration heat value. The SO ₃ content is preferably 0.60 to 0.97% by mass, more preferably 0.60 to 0.95% by mass.
Here, the content of SO ₃ is measured according to JIS R 5202 “Method for chemical analysis of cement” or JIS R 5204 “Method for fluorescent X-ray analysis of cement”.
The medium heat Portland cement clinker preferably contains 42.5 to 49.0% by mass of C ₃ S and 1.5 to 2.5% by mass of C ₃ A. If the contents of C ₃ S and C ₃ A are within the above ranges, the effect of SO _{3 in} the moderately heated Portland cement clinker is effectively exhibited. The content of C ₃ S is more preferably 43.0 to 49.0% by mass, still more preferably 43.0 to 48.0% by mass, and the content of C ₃ A is more preferable. Is 1.6 to 2.3 mass%, more preferably 1.7 to 2.2 mass%. Here, the contents of C ₃ S and C ₃ A are determined by an X-ray diffraction-Riet belt method.

(2) Gypsum The gypsum in the intermediate heat fly ash cement of the present invention is not particularly limited as long as it is used as a gypsum for cement, and examples thereof include dihydrate gypsum and / or hemihydrate gypsum. The content of gypsum in the medium-heated Portland cement is preferably 1.8 to 2.7% by mass in terms of SO ₃ . If the gypsum content is within the above range, an appropriate pot life such as concrete can be secured. The SO ₃ derived from gypsum in medium-heated Portland cement can be calculated from the content (mass%) of dihydrate gypsum and hemihydrate gypsum in medium-heated Portland cement. The gypsum content (% by mass) is determined by various quantitative analysis methods using an X-ray diffraction method such as an X-ray diffraction-Riet belt method or a special sample container disclosed in JP-A-6-242035. It can obtain | require using various thermal-analysis methods, such as the thermogravimetry which uses etc.

(3) Medium-heated Portland cement The medium-heated Portland cement in the medium-heated fly ash cement of the present invention comprises the above-mentioned medium-heated Portland cement clinker and gypsum. Moreover, the brane specific surface area of the intermediate heat fly ash cement is preferably 3000 to 3600 cm ² / g. If the Blaine specific surface area is in this range, the heat insulation temperature characteristics and strength development of the concrete are good. In addition, this brane specific surface area becomes like this. More preferably, it is 3100-3500 cm < ² > / g, More preferably, it is 3200-3500 cm < ² > / g. The Blaine specific surface area is measured according to JIS R 5201 “Cement physical test method”.
The mixing ratio of the moderately hot portland cement in the intermediately heated fly ash cement of the present invention is preferably 65 to 75 parts by mass when the intermediately heated hot ash cement is 100 parts by mass. If the mixing ratio of moderately heated Portland cement is within this range, the heat insulation temperature characteristics and strength development required for mass concrete are compatible. In addition, the mixing ratio of medium heat Portland cement is preferably 65 to 73 parts by mass, and more preferably 66 to 72 parts by mass.

(4) Fly ash The fly ash in the intermediate heat fly ash cement of the present invention is not particularly limited as long as it is a fly ash used as a concrete admixture material or a cement admixture. For example, JIS A 6201 “Fly ash for concrete” And those corresponding to type I or type II as defined in.
The mixing ratio of the fly ash in the intermediate heat fly ash cement of the present invention is preferably 25 to 35 parts by mass when the medium heat fly ash cement is 100 parts by mass. The mixing ratio of fly ash is more preferably 27 to 35 parts by mass, and more preferably 28 to 34 parts by mass.

2. Method for producing medium-heated fly ash cement The medium-heated fly ash cement of the present invention is obtained by mixing the medium-heated Portland cement and fly ash at a mixing ratio of [1]. As a device used for the mixing operation, a device usually used for the production of a mixed cement, that is, a mixing device such as a container rotating type, a container fixing type, and a particle moving type can be used regardless of a continuous type or a batch type.

EXAMPLES Hereinafter, although an Example demonstrates this invention, this invention is not limited to these Examples.
1. Materials to be used (1) Medium-heated Portland cement clinker The medium-heated Portland cement clinkers A to E shown in Table 1 were used.

(2) Manufacture of moderately heated Portland cement Exhausted dihydrate gypsum (manufactured by Sumitomo Metals) and hemihydrate gypsum obtained by heating the exhausted dihydrate gypsum at 140 ° C. A gypsum mixture was obtained by mixing at a mass ratio of 9: 1. Next, after adding 2.2% by mass of the gypsum mixture in terms of SO ₃ to each of the five types of moderately hot Portland cement clinker shown in Table 1, using a batch type ball mill, the Blaine specific surface area is 3350. Simultaneously pulverized to ± 100 cm ² / g to produce moderately heated Portland cement 1-5. Table 2 shows the physical properties and the like of the obtained intermediate heat Portland cement.
The addition rate (mass%) of the gypsum mixture (SO ₃ equivalents) is added rate when the moderate heat Portland cement and 100 wt% (content).

(3) Fly ash The fly ash shown in Table 3 (equivalent to Class II of JIS A 6201 “Fly Ash for Concrete”) was used.

(4) Production of medium-heated fly ash cement For each of medium-heated Portland cements 1 to 5 listed in Table 2, the fly ash listed in Table 3 is mixed so that the mixing ratio of fly ash is 30 parts by mass. Mixing was performed using a batch-type Ladige mixer (model number: FKM-50D) to produce medium heat fly ash cements 1-5. In addition, the total amount of the intermediate heat portland cement and fly ash is 100 parts by mass.

2. Measurement of compressive strength and heat of hydration (2) Compressive strength of mortar Based on JIS R 5201 "Physical test method for cement" The compressive strength test of the mortar of the medium heat fly ash cements 1 to 5 as the material cement was performed. The results are shown in Table 4.

(3) Heat of Hydration of Cement Based on JIS R 5203 “Method of Measuring Heat of Hydration of Cement (Method of Heating Dissolution)”, Table 2 Medium-Hot Portland Cement 1-5 and Based on Medium-Hot Portland Cement The heat of hydration of the medium-heated fly ash cements 1 to 5 produced using the cement material was measured. The results are shown in Table 5.

As shown in Table 4, the ratio of compressive strength at age 28 days / age 7 days includes medium-heated Portland cement clinker with an SO ₃ content of 0.64 wt% and 0.91 wt%. For moderately heated fly ash cements (Examples 1 and 2, respectively), they are 2.07 and 2.08, respectively, which is larger than 1.68 and 1.75 of Comparative Examples 1 and 2. In addition, the ratio of the compressive strength of the material age 28 days / material age 7 days of the comparative example 3 is 2.19 and exceeds Examples 1 and 2, but the absolute value of the compressive strength of the material age 28 days is 30.5 N / mm ^2, which is very low compared to 35.2 N / mm ² and 35.0 N / mm ^{2 in} Examples 1 and 2, respectively. Therefore, it can be said that the intermediate heat fly ash cement of the present invention exhibits high strength and also has a high effect of improving strength development from a material age of 7 days to a material age of 28 days.
In addition, when comparing (ratio of compressive strength of medium-heated fly ash cement age 28 days / age 7 days) / (ratio of compressive strength of medium-heated cement cement age 28 days / age 7 days) Since Examples 1 and 2 are 1.10 and 1.06, and Comparative Examples 1 to 3 are 0.95 to 1.02, the effect of improving the strength development of the intermediate heat fly ash cement of the present invention is In addition, as shown in Table 5, this good strength development can be obtained without an excessive increase in the amount of hydration heat generated. Therefore, the intermediate heat fly ash cement of the present invention is optimal as a cement for mass concrete such as a dam.

Claims (3)

Medium-heated Portland cement 65-75 parts by mass and fly ash 25-35 parts by weight Medium-heated fly ash cement, wherein the medium-heated Portland cement is gypsum and SO ₃ is 0.60-1.00 mass. Medium-heated fly ash cement consisting of medium-heated Portland cement clinker. 2. The medium heat generation according to claim 1, wherein 42.5 to 49.0 mass% of 3CaO · SiO ₂ and 1.5 to 2.5 mass% of 3CaO · Al ₂ O ₃ are contained in the medium heat Portland cement clinker. Fly ash cement. The medium gypsum according to claim 1 or 2, wherein the gypsum is a mixture of dihydrate gypsum and hemihydrate gypsum, and the mixture contains 1.8 to 2.7% by mass in terms of SO ₃ in moderately heated Portland cement. Thermal fly ash cement.