JP2020083733A - Cement composition - Google Patents

Abstract

To provide a cement composition having excellent strength development and small heat of hydration, even when fly-ash is contained.SOLUTION: A cement composition comprising Portland cement clinker powder containing low thermal Portland cement clinker powder and fast strength Portland cement clinker powder, gypsum powder and fly ash powder, in which a ratio of the low thermal Portland cement clinker powder in a total amount of 100 mass% of the low thermal Portland cement clinker powder and early strong Portland cement clinker powder is 5 to 40 mass%, a ratio of the gypsum powder (in terms of SO) in a total of 100 mass% of the Portland cement clinker powder and the gypsum powder (in terms of SO) is 1.0 to 3.0 mass%, a ratio of the fly ash powder in a total amount of 100 mass% of the Portland cement clinker powder, the gypsum powder (in terms of SO) and the fly ash powder exceeds 10 mass% and 40 mass% or lower.SELECTED DRAWING: None

Description

The present invention relates to cement compositions.

Fly ash mixed cement, which is made by replacing a part of the cement with fly ash, forms stable compounds such as calcium silicate hydrate by pozzolan reaction of calcium hydroxide and fly ash to form a dense structure. .. Therefore, the fly ash mixed cement is excellent in watertightness, chemical resistance, and long-term strength development.
Further, since the calorific value of the pozzolanic reaction is smaller than that of the hydration of Portland cement, the heat of hydration of the fly ash mixed cement is less than that of Portland cement. Further, the fly ash itself is spherical fine particles, and therefore, by the ball bearing action, it is possible to improve the fluidity of concrete or the like, and therefore, it is possible to reduce the unit water amount in the production of concrete or the like, It is possible to reduce the drying shrinkage of the hardened product using the fly ash mixed cement.
Further, the fly ash mixed cement can reduce CO ₂ emission during cement production, use of natural resources such as limestone and fossil fuel as raw materials, and can effectively utilize fly ash as a by-product. It has the effect of reducing the environmental load in terms of points.

Although fly ash mixed cement has many advantages as described above, according to the website of the Japan Cement Association, the production amount of fly ash mixed cement in 2014 is 74,000 t/year. The output is only 0.13% of the total cement output (56,700,000 t/year). The reason why the fly ash mixed cement is not widespread in this way is, for example, that the initial strength development is low and thus long-term curing is required until a predetermined strength is obtained.

As a method for improving the strength development of such fly ash mixed cement, fly ash having a preferable quality is evaluated from fly ash of which quality varies depending on the properties of coal as a fuel and the operating state of a thermal power plant. It has been proposed to sort by selecting.
For example, in Patent Document 1, the cement/coal ash ratio (mass ratio) of a mortar or concrete composition containing a large amount of coal ash and having good strength development has a pH of a slurry liquid of 20% of coal ash of 11. When it is 0 or more, it is 0.5 or more, when the pH is 9.0 or more and less than 11.0, it is 0.7 or more, and when the pH is 6.0 or more and less than 9.0, 1. It is set to 0 or more.
Further, in Patent Document 2, a fly ash suitable for producing a cement having stable and good strength development contains α-quartz having a lattice constant of 0.4935 nm or less obtained by Rietveld analysis, It is described that the BET specific surface area is 5.0 m ² /g or less.

JP-A-9-156971 JP, 2011-20867, A

The inventions described in Patent Documents 1 and 2 are a method of changing the cement/coal ash ratio depending on the properties of coal ash, and a method of selecting fly ash using a special evaluation method, and the strength of fly ash mixed cement. It does not directly improve the expression.
Therefore, an object of the present invention is to develop strength (especially, mortar compressive strength at 3 to 28 days of age) even when fly ash is included (for example, more than 10% by mass and 40% by mass or less). It is to provide a cement composition which is excellent in heat resistance and has a low heat of hydration.

The present inventor, as a result of intensive studies to solve the above problems, a Portland cement clinker powder containing a low-heat Portland cement clinker powder and an early-strength Portland cement clinker powder, a gypsum powder, and a cement composition containing a fly ash powder. Therefore, the ratio of the low heat Portland cement clinker powder and the early strength Portland cement clinker powder in the total amount 100% by mass, and the total amount of the Portland cement clinker powder and the gypsum powder (SO ₃ conversion) 100% by mass. The ratio of the gypsum powder (SO ₃ conversion) and the ratio of fly ash powder in the total amount of 100% by mass of Portland cement clinker powder, gypsum powder (SO ₃ conversion) and fly ash powder are within specific numerical ranges. It was found that the above-mentioned objects can be achieved by the cement composition of the present invention, and the present invention has been completed.

That is, the present invention provides the following [1] to [2].
[1] A cement composition containing Portland cement clinker powder, gypsum powder, and fly ash powder, wherein the Portland cement clinker powder contains low-heat Portland cement clinker powder and early-strength Portland cement clinker powder. Yes, the ratio of the low heat Portland cement clinker powder in the total amount 100% by mass of the low heat Portland cement clinker powder and the early strong Portland cement clinker powder is 5 to 40% by mass. The ratio of the gypsum powder (SO ₃ conversion) in the total amount of 100% by mass of the powder (SO ₃ conversion) is 1.0 to 3.0% by mass, and the Portland cement clinker powder and the gypsum powder (SO _{3 ).} (Conversion) and the ratio of the fly ash powder in the total 100 mass% of the fly ash powder is more than 10 mass% and 40 mass% or less.
[2] The cement composition according to [1], which contains limestone powder having a Blaine specific surface area of 5,000 cm ² /g or more, and/or blast furnace slag powder having a Blaine specific surface area of 3,000 cm ² /g or more.

Even when the cement composition of the present invention contains fly ash (for example, more than 10% by mass and 40% by mass or less), strength development (particularly, mortar compressive strength at a material age of 3 to 28 days). It has excellent heat resistance and low heat of hydration.

The cement composition of the present invention is a cement composition containing Portland cement clinker powder, gypsum powder, and fly ash powder, wherein Portland cement clinker powder is a low heat Portland cement clinker powder, and early strength Portland cement clinker powder. The proportion of the low-heat Portland cement clinker powder and the early-hardening Portland cement clinker powder in the total amount of 100% by mass of the low-heat Portland cement clinker powder is 5 to 40% by mass. The proportion of the gypsum powder (SO ₃ conversion) in the total amount of 100% by mass (SO ₃ conversion) is 1.0 to 3.0% by mass, and Portland cement clinker powder, gypsum powder (SO ₃ conversion) and frying. The proportion of fly ash powder in the total amount of ash powder of 100 mass% is more than 10 mass% and 40 mass% or less.
Hereinafter, the present invention will be described in detail.

1. Constituent Material of Cement Composition (1) Portland Cement Clinker Powder The Portland cement clinker powder used in the present invention (hereinafter, also simply referred to as “cement clinker powder”) is a low heat Portland cement clinker powder and an early strong Portland cement clinker. It contains powder.
It is also referred to as alite (3CaO.SiO ₂ ; hereinafter, “C ₃ S”) calculated using the Borg equation in the cement clinker powder. From the viewpoints of fluidity of the cement composition, improvement of strength development, and reduction of heat of hydration, the content is preferably 47.0 to 64.0% by mass, more preferably 49.0 to 62. 0.0% by mass, particularly preferably 51.0 to 60.0% by mass.
Further, the content of belite (2CaO·SiO ₂ ; hereinafter also referred to as “C ₂ S”) calculated using the Borg equation in the cement clinker powder is determined by the fluidity and strength development of the cement composition. From the viewpoint of improvement and reduction of heat of hydration, it is preferably 9.0 to 30.0 mass%, more preferably 12.0 to 27.0 mass%, and particularly preferably 14.0 to 25.0 mass%. Is.

The content of the aluminate phase (3CaO·Al ₂ O ₃ ; hereinafter, also referred to as “C ₃ A”) calculated using the Borg equation in the cement clinker powder is the fluidity and strength of the cement composition. From the viewpoint of improving the expression and reducing the heat of hydration, it is preferably 5.0 to 10.5% by mass, more preferably 6.0 to 10.0% by mass, and particularly preferably 7.0 to 9. It is 5% by mass.
Further, in the cement clinker powder, ferrite phase calculated using the Borg type _{(4CaO · Al 2 O 3 ·} Fe 2 O 3;. Hereinafter referred to as _"C 4 AF") the content of, the cement composition From the viewpoints of improving fluidity, strength development, and reducing heat of hydration, it is preferably 8.0 to 9.0 mass%, more preferably 8.1 to 8.9 mass%, and particularly preferably 8. It is 2 to 8.8% by mass.

In the present specification, C ₃ S in the cement clinker _{powder, C 2 S, C 3 A} , each content of C ₄ AF, as a percentage of cement clinker powder total amount (100 mass%) in the cement clinker raw material It is calculated based on the chemical composition of cement clinker powder (calcined product) using the following Borg's formula.
C ₃ S (mass %)=(4.07×CaO (mass %))-(7.60×SiO ₂ (mass %))-(6.72×Al ₂ O ₃ (mass %))-(1 .43×Fe ₂ O ₃ (mass %))
C ₂ S (mass %)=(2.87×SiO ₂ (mass %))−(0.754×C ₃ S (mass %))
C ₃ A (mass %)=(2.65×Al ₂ O ₃ (mass %))−(1.69×Fe ₂ O ₃ (mass %))
C ₄ AF (mass %)=3.04×Fe ₂ O ₃ (mass %)

In the present invention, the inclusion of C ₂ S of the low heat Portland cement clinker and the early strength Portland cement clinker used for the preparation of the cement clinker powder (including the low heat Portland cement clinker powder and the early strength Portland cement clinker powder). As for the mineral composition such as the ratio, the numerical value of the content rate of C ₂ S etc. of the cement clinker powder obtained by the preparation is preferably within the above numerical range.
Further, the cement clinker powder may contain Portland cement clinker powder (hereinafter, also referred to as “other clinker powder”) other than the low heat Portland cement clinker powder and the early strong Portland cement clinker powder. From the viewpoints of fluidity, strength development and the like, it is preferable to use only low heat Portland cement clinker powder and early-strength Portland cement clinker powder.
The proportion of the other clinker powder in the total amount of the cement clinker powder is preferably 10% by mass or less, more preferably 5% by mass or less, and particularly preferably 0% by mass.

The Blaine specific surface area of the cement clinker powder is preferably 3,700 to 5,200 cm ² /g, and more preferably 3,800 from the viewpoint of fluidity and strength development of the cement composition and further reduction of the cost of grinding. ˜5,000 cm ² /g, particularly preferably 4,000 to 4,800 cm ² /g.

(2) Gypsum powder Examples of the gypsum powder used in the present invention include powders such as gypsum dihydrate, gypsum hemihydrate, and anhydrous gypsum. These may be used alone or in combination of two or more.
Above all, it is preferable to use a mixture of gypsum dihydrate and gypsum hemihydrate from the viewpoint of fluidity and strength development of the cement composition. The proportion of hemihydrate gypsum in the total amount of dihydrate gypsum and hemihydrate gypsum of 100% by mass is preferably 10 to 95% by mass in terms of SO _{3 in} terms of fluidity and strength development of the cement composition. It is preferably 20 to 90% by mass, particularly preferably 30 to 85% by mass.
Also, the Blaine specific surface area of the gypsum powder, from the viewpoint of fluidity and strength development of the cement composition, preferably 5,000~15,000cm ² / g, more preferably 6,000~14,000cm ² / g Is.

(3) Fly ash powder The fly ash powder used in the present invention has a Blaine specific surface area of preferably 1,500 to 8,000 cm ² /g, more preferably from the viewpoint of fluidity and strength development of the cement composition. 2,000 to 7,000 cm ² /g, more preferably 2,500 to 6,000 cm ² /g, further preferably 2,700 to 5,000 cm ² /g, particularly preferably 2,900 to 4,000 cm ^2. /G.
The mass of each of Na ₂ O, K ₂ O, MgO, SO ₃ , TiO ₂ , P ₂ O ₅ , and MnO in the unit mass of the fly ash powder preferably satisfies the following formula (1). ..
(Na ₂ O+0.658×K ₂ O)/(MgO+SO ₃ +TiO ₂ +P ₂ O ₅ +MnO)=0.10 to 1.50 (1)
The mass ratio derived from the left side of the above formula (1) is preferably 0.10 to 1.50, more preferably 0.20 to 1.00, still more preferably 0.25 to 0.80, still more preferably 0. 0.28 to 0.70, and particularly preferably 0.30 to 0.60. When the mass ratio is within the above numerical range, the strength development of the cement composition is further improved. Further, when the mass ratio is 1.50 or less, the drying shrinkage of the hardened body made of the cement composition can be further reduced.

Quartz in fly ash powder, the value of the lattice volume obtained by using the Rietveld analysis method, the improvement of the strength development of the cement composition, and the reduction of dry shrinkage of the cured product made of the cement composition From the viewpoint, it is preferably 113.5 to 114.5Å ³ , more preferably 113.6 to 114.4Å ³ , and particularly preferably 113.7 to 114.3Å ³ .
The fly ash powder usually contains quartz in a proportion of 5 to 25% by mass.
The value of the lattice volume of the quartz in the fly ash powder obtained using the Rietveld analysis method is based on the X-ray diffraction diagram of the fly ash powder, for example, analysis software manufactured by Bruker (trade name: “TOPAS”). version 2.1") and crystal structure data (ICDD number:3311161 (Quartz) used to search the database) obtained from a PDF database of ICDD (International Center for Diffraction Data).

(4) Other constituent materials (limestone powder and/or blast furnace slag powder)
The cement composition of the present invention may further contain limestone powder and/or blast furnace slag powder.
The Blaine specific surface area of the limestone powder is 5,000 cm ² /g or more, preferably 5,200 to 15,000 cm ² /g, more preferably 5,400 to 14,000 cm ² /g, and further preferably 5,500 to. It is 13,000 cm ² /g, particularly preferably 5,700 to 12,000 cm ² /g. When the Blaine specific surface area is 5,000 cm ² /g or more, the strength development of the cement composition can be further improved.
Blaine specific surface area of the blast furnace slag powder, 3,000 cm ² / g or more, preferably 3,200~6,000cm ² / g, more preferably 3,500~5,500cm ² / g, more preferably 3,800 ˜5,200 cm ² /g, particularly preferably 4,000 to 5,000 cm ² /g. When the Blaine specific surface area is 3,000 cm ² /g or more, the strength development of the cement composition can be further improved.

2. Composition of cement composition (mixing of constituent materials)
In the cement composition of the present invention, the proportion of the low-heat Portland cement clinker powder in the total amount of the low-heat Portland cement clinker powder and the early-strength Portland cement clinker powder of 100% by mass is 5 to 40% by mass, preferably 10 to 35% by mass. , And more preferably 15 to 30% by mass. If the proportion is less than 5% by mass, the heat of hydration of the cement composition will be high. In addition, the long-term strength development of the cement composition is reduced. If the proportion exceeds 40% by mass, the strength developability of the cement composition will decrease. Further, by setting the above ratio within the above numerical range, the content rate of C ₃ S or the like in the cement clinker powder calculated using the Borg equation can be within the above numerical range.

In the cement composition of the present invention, the proportion of cement clinker powder and gypsum powder gypsum powder of the total amount 100% by mass of the (SO ₃ conversion) (SO ₃ equivalent), 1.0 to 3.0 wt%, preferably The amount is 1.5 to 2.9% by mass, more preferably 1.8 to 2.8% by mass, and particularly preferably 1.8 to 2.6% by mass. If the proportion is less than 1.0% by mass, the fluidity of the cement composition will decrease. When the ratio exceeds 3.0% by mass, the strength developability of the cement composition decreases.
The ratio of total SO ₃ content of the total amount 100 mass% of the cement clinker powder and gypsum powder (SO ₃ equivalents), from the viewpoint of fluidity and strength development of the cement composition, preferably 1.5 to 3 It is 0.5% by mass, more preferably 1.7 to 3.2% by mass, further preferably 2.0 to 3.0% by mass, and particularly preferably 2.3 to 3.0% by mass.

In the cement composition of the present invention, the proportion of fly ash powder in the total amount of 100 mass% of cement clinker powder, gypsum powder (SO ₃ conversion) and fly ash powder is more than 10 mass% and 40 mass% or less, preferably Is 12 to 35% by mass, more preferably 15 to 30% by mass, and particularly preferably 16 to 25% by mass. When the proportion is 10% by mass or less, the fluidity of the cement composition is lowered. In addition, the heat of hydration of the cement composition increases. In addition, it is not preferable from the viewpoint of promoting effective utilization of fly ash. If the proportion exceeds 40% by mass, the strength developability of the cement composition will decrease.

In the cement composition of the present invention, cement clinker powder, gypsum powder (SO ₃ conversion), fly ash powder, and limestone powder and/or blast furnace slag powder in a total amount of 100% by mass of limestone powder and/or blast furnace slag powder. Is preferably 0 to 10.0% by mass, more preferably 1.0 to 9.0% by mass, and particularly preferably 2.0 to 8.0% by mass. When the ratio is within the above numerical range, the strength development of the cement composition is further improved.

The cement composition of the present invention includes, in addition to the above-mentioned constituent materials (cement clinker powder, gypsum powder, fly ash powder, and limestone powder and/or blast furnace slag powder), if necessary, silica stone powder and cement clinker. The amount may be 5.5 parts by mass or less based on 100 parts by mass of the powder.
The Blaine specific surface area of the cement composition of the present invention is preferably 3,500 to 5,500 cm ² /g, more preferably 3,600 to 5, from the viewpoint of fluidity and strength development of the cement composition. 000cm ² / g, particularly preferably 3,700~4,500cm ² / g.

3. Method for producing cement composition Examples of the method for producing the cement composition of the present invention include the following methods (a) to (c).
(A) In advance, a low heat Portland cement clinker and gypsum were crushed at the same time to prepare a low heat Portland cement clinker-containing powder (hereinafter also referred to as "LC"), and an early-strength Portland cement clinker and gypsum were crushed simultaneously. A high-strength Portland cement clinker-containing powder (hereinafter, also referred to as “HC”) was prepared, and then LC, HC, fly ash powder, and optionally limestone powder (having a Blaine specific surface area of 5,000 cm ² / g or more) and/or blast furnace slag powder (having a Blaine specific surface area of 3,000 cm ² /g or more) are mixed. In this method, the low heat Portland cement clinker and gypsum are pulverized by Is preferably 3,300 to 6,000 cm ² /g, more preferably 3,350 to 5,500 cm ² /g, further preferably 3,400 to 5,000 cm ² /g, and particularly preferably 3,400 to It is preferable to carry out until the pressure reaches 4,000 cm ² /g. In addition, as for the crushing of the early strength Portland cement clinker and gypsum, the crushed product has a Blaine specific surface area of preferably 4,200 to 4,700 cm ² /g, more preferably 4,250 to 4,650 cm ² /g, and particularly preferably. Is preferably performed up to 4,300 to 4,600 cm ² /g.

(B) In advance, a low-heat Portland cement clinker, gypsum, and optionally limestone and/or blast furnace slag are simultaneously crushed to produce a low-heat Portland cement clinker-containing powder (LC), and a high-strength Portland cement clinker is also used. A method of simultaneously crushing gypsum to prepare an early-strength Portland cement clinker-containing powder (HC), and then mixing LC, HC, and fly ash powder, wherein low-heat Portland cement clinker, gypsum, limestone and/or In the pulverization of blast furnace slag, the pulverized product has a Blaine specific surface area of preferably 3,300 to 6,000 cm ² /g, more preferably 3,350 to 5,500 cm ² /g, and further preferably 3,400 to 5,. It is preferable to perform the treatment until the pressure reaches 000 cm ² /g, particularly preferably 3,400 to 4,000 cm ² /g. By the pulverization, the limestone powder contained in the pulverized product has a Blaine specific surface area of 5,000 cm ² /g or more. Further, by the pulverization, the blast furnace slag powder contained in the pulverized product has a Blaine specific surface area of 3,000 cm ² /g or more.
In addition, as for the crushing of the early strength Portland cement clinker and gypsum, the crushed product has a Blaine specific surface area of preferably 4,200 to 4,700 cm ² /g, more preferably 4,250 to 4,650 cm ² /g, and particularly preferably. Is preferably performed up to 4,300 to 4,600 cm ² /g.

(C) A low-heat Portland cement clinker and gypsum are simultaneously crushed in advance to produce a low-heat Portland cement clinker-containing powder (LC), and high-speed Portland cement, gypsum, and, if necessary, limestone and/or blast furnace slag. And a method of mixing LC, HC, and fly ash powder with each other to produce a high-strength Portland cement clinker-containing powder (HC) at the same time. Has a Blaine specific surface area of preferably 3,300 to 6,000 cm ² /g, more preferably 3,350 to 5,500 cm ² /g, further preferably 3,400 to 5,000 cm ² /g, and particularly preferably It is preferable to carry out until it reaches 3,400 to 4,000 cm ² /g.
In addition, as for the crushing of early strength Portland cement clinker, gypsum, limestone and/or blast furnace slag, the Blaine specific surface area of the crushed product is preferably 4,200 to 4,700 cm ² /g, more preferably 4,250 to 4, It is preferable to carry out until the pressure reaches 650 cm ² /g, particularly preferably 4,300 to 4,600 cm ² /g. By the pulverization, the limestone powder contained in the pulverized product has a Blaine specific surface area of 5,000 cm ² /g or more. Further, by the pulverization, the blast furnace slag powder contained in the pulverized product has a Blaine specific surface area of 3,000 cm ² /g or more.

The cement composition of the present invention is mixed with water and other materials optionally blended (for example, fine aggregate, coarse aggregate, cement dispersant, etc.) to give a paste, mortar, or Used as concrete.
As the cement dispersant, a water reducing agent, an AE water reducing agent, a high performance water reducing agent, or a high performance AE water reducing agent, such as a lignin type, naphthalene sulfonic acid type, melamine type, or polycarboxylic acid type, can be used.
When the cement composition of the present invention is used as mortar or concrete, as an aggregate, a normal fine aggregate used in the production of mortar or concrete (for example, river sand, land sand, crushed sand, etc.) or coarse bone Wood (eg, river gravel, mountain gravel, crushed stone, etc.) can be used. Further, as a part or all of the aggregate, molten slag (for example, one produced by melting one or more selected from municipal waste, municipal waste incineration ash, and sewage sludge incineration ash), blast furnace slag, steelmaking slag, Waste materials such as copper slag, insulator scrap, glass cullet, ceramic waste material, clinker ash, waste brick, and concrete waste material can also be used.
In addition, if necessary, an admixture such as an air entraining agent or an antifoaming agent may be used within a range not hindering the purpose of the present invention.

Hereinafter, the present invention will be specifically described by way of examples, but the present invention is not limited to these examples.
[Materials used]
(1) Low heat Portland cement 1 (manufactured by Taiheiyo Cement Co., Ltd.); C ₃ S: 26.7 mass%, C ₂ S: 56.7 mass%, C ₃ A: 1.8 mass%, C ₄ AF: 9. 1% by mass, gypsum (SO ₃ conversion): 1.8% by mass, total SO ₃ amount: 2.3% by mass, Blaine specific surface area: 3,440 cm ² /g
(2) Low heat Portland cement 2 (manufactured by Taiheiyo Cement Co.); C ₃ S: 26.7 mass%, C ₂ S: 56.7 mass%, C ₃ A: 1.8 mass%, C ₄ AF: 9. 1% by mass, gypsum (SO ₃ conversion): 1.8% by mass, total SO ₃ amount: 2.3% by mass, Blaine specific surface area: 4,500 cm ² /g
(3) Low heat Portland cement 3 (manufactured by Taiheiyo Cement Co.); C ₃ S: 26.7 mass%, C ₂ S: 56.7 mass%, C ₃ A: 1.8 mass%, C ₄ AF: 9. 1% by mass, gypsum (SO ₃ conversion): 1.8% by mass, total SO ₃ amount: 2.3% by mass, Blaine specific surface area: 5,500 cm ² /g
(4) Early strength Portland cement (manufactured by Taiheiyo Cement Co.); C ₃ S: 65.2 mass%, C ₂ S: 8.6 mass%, C ₃ A: 9.5 mass%, C ₄ AF: 8. 4% by mass, gypsum (SO ₃ conversion): 2.3% by mass, total SO ₃ amount: 3.0% by mass, Blaine specific surface area: 4,600 cm ² /g
(5) Ordinary Portland cement (manufactured by Taiheiyo Cement Co.); C ₃ S: 60.1% by mass, C ₂ S: 13.1% by mass, C ₃ A: 9.0% by mass, C ₄ AF: 9.8. Mass %, gypsum (SO ₃ conversion): 2.0 mass %, Blaine specific surface area: 3,250 cm ² /g
(6) Fly ash powder 1; Blaine specific surface area: 3,760 cm ² /g, mass ratio ((Na ₂ O+0.658×K ₂ O)/(MgO+SO ₃ +TiO ₂ +P ₂ O ₅ +MnO): 0.51, Quartz lattice volume (Å ³ ): 113.9
(7) Fly ash powder 2; Blaine specific surface area: 5,000 cm ² /g, mass ratio ((Na ₂ O+0.658×K ₂ O)/(MgO+SO ₃ +TiO ₂ +P ₂ O ₅ +MnO):0.51, Quartz lattice volume (Å ³ ): 113.9
(8) Limestone powder; Blaine specific surface area: 8,500 cm ² /g
(9) Fine aggregate; standard sand defined in "JIS R 5201 (Cement physical test method)" (10) Water reducing agent: Polycarboxylic acid type high performance AE water reducing agent, manufactured by BASF Japan Ltd., trade name "Master Glenium"SP8N"
(11) Defoaming agent; nonionic surfactant, manufactured by Nichika Kagaku Co., Ltd., trade name "Formlex 747"
(12) Water; tap water

[Example 1]
Low-heat Portland cement 1, early-strength Portland cement, fly ash powder 1, and limestone powder were mixed in an amount such that each material satisfies the following conditions (1) to (3) to prepare a cement composition 1.
(1) The proportion of low heat Portland cement in the total amount 100% by mass of low heat Portland cement and early strength Portland cement is 15% by mass (2) The total amount 100 of low heat Portland cement, early strength Portland cement and fly ash powder The ratio of fly ash powder in mass% is 18.6 mass %. (3) Low heat Portland cement 1, early strength Portland cement, fly ash powder and limestone powder Must be 3.7% by mass

[Example 2]
Cement composition in the same manner as in Example 1 except that the amount of each material was determined so that the proportion of low-heat Portland cement in the total amount of low-heat Portland cement and early-strength Portland cement was 100% by weight. 2 was prepared.
[Example 3]
A cement composition 3 was prepared in the same manner as in Example 1 except that the low heat Portland cement 2 was used in place of the low heat Portland cement 1.
[Example 4]
A cement composition 4 was prepared in the same manner as in Example 2 except that the low heat Portland cement 2 was used in place of the low heat Portland cement 1.

[Example 5]
A cement composition 5 was prepared in the same manner as in Example 1 except that the low heat Portland cement 3 was used in place of the low heat Portland cement 1.
[Example 6]
A cement composition 6 was prepared in the same manner as in Example 2 except that the low heat Portland cement 3 was used in place of the low heat Portland cement 1.
[Example 7]
Cement composition 7 was prepared in the same manner as in Example 5 except that fly ash powder 2 was used instead of fly ash powder 1.
[Example 8]
A cement composition 8 was prepared in the same manner as in Example 6 except that the fly ash powder 2 was used instead of the fly ash powder 1.

[Comparative Example 1]
The early-strength Portland cement and the fly ash powder 1 were mixed in an amount such that the ratio of the fly-ash powder 1 in the total amount of the early-strength Portland cement and the fly ash powder 1 was 100% by mass was 18.0% by mass, Cement composition 9 was prepared.
[Comparative example 2]
Cement composition in the same manner as in Example 1 except that the amount of each material was determined so that the proportion of low-heat Portland cement was 50% by mass in the total amount of 100% by mass of low-heat Portland cement and early-strength Portland cement. 10 was prepared.

[Comparative Example 3]
Ordinary Portland cement and fly ash powder 1 were mixed so that the ratio of fly ash powder 1 in the total amount of 100% by weight of ordinary Portland cement and fly ash powder 1 would be 18.0% by mass, and a cement composition 11 Was prepared.

In each of the obtained cement compositions 1 to 11, the proportion of the low heat Portland cement clinker powder in 100% by mass of the total amount of the low heat Portland cement clinker powder and the early strength Portland cement clinker powder, and the Portland cement clinker powder (Examples 1 to 1). 8 and Comparative Example 2: Low heat Portland cement clinker powder and early strength Portland cement clinker powder, Comparative Example 1: Early strength Portland cement clinker powder, Comparative Example 3: Normal Portland cement clinker powder) and gypsum powder (SO ₃ conversion). ) Of the gypsum powder (SO ₃ equivalent) in the total amount of 100% by mass, and the proportion of fly ash powder in the total amount of 100 mass% of Portland cement clinker powder, gypsum powder (SO ₃ equivalent) and fly ash powder. , Shown in Table 1.

In the Portland cement clinker powder contained in the cement compositions 1, 3, 5, and 7, the content of C ₃ S is 59.4% by mass, the content of C ₂ S is 15.4% by mass, and the content of C ₃ A is contained. The content was 8.4% by mass, and the C ₄ AF content was 8.5% by mass.
In the Portland cement clinker powder contained in the cement compositions 2, 4, 6, and 8, the C ₃ S content is 53.7 mass%, the C ₂ S content is 23.0 mass%, and the C ₃ A content is C ₃ A. Content was 7.2% by mass, and C ₄ AF content was 8.6% by mass.
In the Portland cement clinker powder contained in the cement composition 10, the C ₃ S content was 46.0 mass %, the C ₂ S content was 32.7 mass %, and the C ₃ A content was 5. The content of C ₄ AF was 7 mass %, and the content of C ₄ AF was 8.8 mass %.
Percentage of total SO ₃ content of the total amount 100 mass% of the cement clinker powder and gypsum powder in 1～8,10 resulting cement compositions in Examples 1 to 8 and Comparative Example 2 (SO ₃ equivalent), It was 2.7-2.9 mass %.
The Blaine specific surface area of the cement clinker powder in the cement compositions 1 to 8 and 10 obtained in Examples 1 to 8 and Comparative Example 2 was 4,000 to 4,800 cm ² /g.
Moreover, the Blaine specific surface area of the gypsum powder in the cement compositions 1-11 obtained in Examples 1-8 and Comparative Examples 1-3 was 8,000-12,000 cm< ² >/g.
Further, the Blaine specific surface areas of the cement compositions 1 to 11 obtained in Examples 1 to 8 and Comparative Examples 1 to 3 were 3,700 to 4,500 cm ² /g.
The Blaine specific surface area of a specific material (for example, gypsum powder) in the cement composition is determined by observing the cement composition with a scanning electron microscope (SEM) to identify particles of the material in the cement composition. After determining the average particle size of the particles, it can be estimated from the average particle size.

The following evaluation was performed about the obtained cement composition.
(1) Measurement of mortar flow The mass ratio of water and cement composition (water/cement composition) is 0.3, and the mass ratio of fine aggregate and cement composition (fine aggregate/cement composition) is 1.4. The mass ratio of the defoaming agent to the cement composition (defoaming agent/cement composition) is 0.001, and the mass ratio of the cement dispersant to the cement composition (cement dispersant/cement composition) is 0.0065. Mortars were prepared by mixing these materials, such as cement compositions, in amounts. The kneading of these materials was performed in accordance with "JIS R 5201 (physical test method for cement)" using a Hobart mixer (however, the kneading time was set to be 2 minutes longer than the time described here). I went. At the time of kneading, the cement dispersant and the defoaming agent were added to the mixer at the same time as water.
The obtained mortar was kneaded using a slump cone described in "JIS A 1171 (Testing method for polymer cement mortar)" according to the flow test of "JIS R 5201 (Physical testing method for cement)". Immediately after, the mortar flow value was measured without performing 15 falling motions.
(2) Measurement of mortar compressive strength Based on "JIS R 5201 (Cement physical test method)", the mortar compressive strength at each time of 3 days, 7 days and 28 days was measured.
(3) Measurement of heat of hydration Based on "JIS R 5203 (Physical test method for cement)", heat of hydration was measured at each time point of 7 days and 28 days of age.
The respective results are shown in Table 2.

From Table 2, the mortar compressive strength (37.2 N/mm ² ) and the age of 7 days of the cement composition of Comparative Example 1 (a mixture of early-strength Portland cement and fly ash powder) at 3 days of age The mortar compressive strength (45.3 N/mm ² ) in Examples 1 to 8 was 3 days after mortar compressive strength (28.7 to 34.7 N/mm ² ) and the material was after 7 days. Although it was larger than the mortar compressive strength (37.8 to 44.7 N/mm ² ), the mortar compressive strength (54.2 N/mm ² ) of the cement composition of Comparative Example 1 at the age of 28 days was It was smaller than the mortar compressive strength (56.4 to 60.0 N/mm ² ) at 28 days of age in Examples 1 to 8. The heat of hydration of each age of the cement composition of Comparative Example 1 (age 3 days: 372J, age 7 days: 405J) was the heat of hydration at each age of Examples 1 to 8 (age. 7 days: 310 to 350 J, material age 28 days: 364 to 391 J).
That is, the cement composition of Comparative Example 1 had a higher mortar compressive strength at 3 and 7 days of age, but was inferior in that it had a higher heat of hydration, as compared with the cement compositions of Examples 1 to 8. You can see that

In addition, the cement composition of Comparative Example 2 (the proportion of the low-heat Portland cement clinker powder in the total amount of the low-heat Portland cement clinker powder and the early-hardening Portland cement clinker powder is 100% by mass is 50% by mass) at each age. The heat of hydration (3 days old: 265 J, 7 days old: 312 J) was smaller than the heat of hydration at each age of Examples 1 to 8, but the mortar compressive strength at each age (age) 3 days: 22.3 N/mm ² , age 7 days: 29.7 N/mm ² , age 28 days: 54.2 N/mm ² ) is based on the mortar compressive strength at each age of Examples 1 to 8. Was also small.
That is, the cement composition of Comparative Example 2 is inferior to the cement compositions of Examples 1 to 8 in that the heat of hydration is small but the mortar compressive strength at each age is small. Recognize.

Furthermore, the heat of hydration (age 3 days: 307J, age 7 days: 350J) of each age of the cement composition of Comparative Example 3 (a mixture of ordinary Portland cement and fly ash powder) was carried out. It was smaller than the heat of hydration at each age of Examples 1 to 8, but the mortar compressive strength after 3 days of age (27.6 N/mm ² ) and the mortar compressive strength after 28 days of age (54.9 N/ mm ² ) is smaller than the mortar compressive strength at each age of Examples 1 to 8, and the mortar compressive strength (41.7 N/mm ² ) at 7 days of age is that of Examples 1 to 8 It was similar to the mortar compressive strength in the day. Further, the mortar flow (288 mm) of Comparative Example 3 was smaller than the mortar flow (295-310 mm) of Examples 1-8.
That is, the cement composition of Comparative Example 3 has a smaller heat of hydration but a smaller mortar compressive strength (especially ages 3 and 28 days) and mortar as compared with the cement compositions of Examples 1 to 8. It turns out that it is inferior in that the flow is small.

Claims (2)

A cement composition containing Portland cement clinker powder, gypsum powder, and fly ash powder,
The above-mentioned Portland cement clinker powder contains low heat Portland cement clinker powder, and early strong Portland cement clinker powder,
The proportion of the low-heat Portland cement clinker powder in the total amount of the low-heat Portland cement clinker powder and the early strength Portland cement clinker powder of 100% by mass is 5 to 40% by mass,
Ratio of the Portland cement clinker powder and said gypsum powder of the total amount 100 mass% of the gypsum powder (SO ₃ conversion) (SO ₃ equivalent), and 1.0 to 3.0 wt%,
The ratio of the fly ash powder in the total amount of 100 mass% of the Portland cement clinker powder, the gypsum powder (SO ₃ conversion) and the fly ash powder is more than 10 mass% and 40 mass% or less. And a cement composition. The cement composition according to claim 1, comprising limestone powder having a Blaine specific surface area of 5,000 cm ² /g or more, and/or blast furnace slag powder having a Blaine specific surface area of 3,000 cm ² /g or more.