JP2016023105A - Concrete binder for blast furnace cement concrete - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a blast furnace cement concrete having excellent contraction crack resistance similar to or more than normal concrete.SOLUTION: A concrete binder for blast furnace cement concrete is provided which contains portland cement, blast furnace slag, calcium carbonate and gypsum, with the content of the blast furnace slag being over 5 mass% and 60 mass% or less, the content of the calcium carbonate being 2 mass% to 11 mass%, the content of the gypsum being 5 mass% to 10 mass% in terms of anhydride and 0.9 or more times the content of the calcium carbonate.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a concrete binder for blast furnace cement concrete.

A hardened concrete body is a basic structure that creates social capital such as buildings and civil engineering structures. In recent years, as an environmental measure such as prevention of global warming, it has been strongly demanded to suppress the amount of CO ₂ generated from these hardened concrete bodies.

In order to suppress the amount of CO ₂ generated from hardened concrete, an appropriate amount of blast furnace slag, which is a by-product of the steel industry, is used instead of Portland cement, which has been widely used as a cement material for the concrete binder. It is known that the amount of CO ₂ generated can be significantly suppressed by using a binder mixed with Portland cement (see Patent Document 1).

  As described above, concrete using blast furnace slag (hereinafter referred to as “blast furnace cement concrete”) greatly contributes to reducing the environmental load, and is expected to be applied to RC building structures. However, blast furnace cement concrete is inferior in neutralization resistance and shrinkage cracking resistance compared to concrete using ordinary Portland cement (hereinafter referred to as “ordinary concrete”) as the cement material constituting the concrete binder. However, the present situation is that it is almost limited to the application to underground structures that have been in a humid environment for a long time.

  In order to apply blast furnace cement concrete, which is such an environmentally friendly concrete, to the upper frame, it is important to improve shrinkage cracking resistance. However, recent findings indicate that shrinkage cracking resistance of blast furnace cement concrete is It has been pointed out that it tends to decrease especially at high temperatures compared to ordinary concrete. One of the major factors is that blast furnace cement concrete has a higher self-shrinkage strain at high temperatures, and blast furnace cement concrete produces more gel water than ordinary concrete. It has also been pointed out that much water is needed. Considering these facts, it is presumed that since the concrete consumes a lot of water for hydration, the inside of the concrete becomes dry and self-shrinkage strain increases, and as a result, shrinkage cracking resistance is lowered. On the other hand, it is generally known that blast furnace cement concrete is sensitively affected by curing at the early stage of curing, and is consistent with the above-mentioned knowledge obtained in recent years.

  In order to solve these problems, a curing method for actively supplying moisture at the early stage of curing is disclosed for blast furnace cement concrete (see Patent Document 2). However, it is difficult to perform wet curing at the initial stage of curing with vertical members such as walls and pillar members, and it can be said that application of such means is almost impractical.

  In addition, as an attempt to improve the physical properties of blast furnace cement concrete to improve the strength and durability of blast furnace cement concrete, a cement composition for blast furnace cement concrete to which gypsum and calcium carbonate are added (Patent Document 3). In addition, in a cement composition having such a composition, the blending ratio of calcium carbonate and gypsum is further increased for the blast furnace cement concrete in which the blending ratio of calcium carbonate is relatively large. A cement composition (see Patent Document 4) and the like are also disclosed.

JP2013-203635A JP 2013-034945 A Japanese Patent Laid-Open No. 5-116996 International Publication No. 2007/046297

  The blast furnace cement concrete made of the cement composition described in Patent Documents 3 and 4 is intended to increase the strength of concrete based on the premise of improving the sulfate resistance and steam curing, and improving the resistance to shrinkage cracking. Is not paid attention to. As means for improving the shrinkage cracking resistance of blast furnace cement concrete, the improvement based on the above knowledge is insufficient, and further development of blast furnace cement concrete having excellent shrinkage cracking resistance has been desired.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a blast furnace cement concrete having excellent shrinkage cracking resistance equivalent to or higher than that of ordinary concrete.

  The present inventors obtained new knowledge by paying attention to the action of gypsum during the progress of the curing reaction of blast furnace cement concrete. And based on this knowledge, it is possible to remarkably improve the shrinkage cracking resistance of blast furnace cement concrete by optimizing the mixing ratio of calcium carbonate and gypsum in the concrete binder to its own specific range. As a result, the present invention has been completed. Specifically, the present invention provides the following.

  (1) A concrete binder for blast furnace cement concrete, which contains Portland cement, blast furnace slag, calcium carbonate, and gypsum, and the content of the blast furnace slag exceeds 5 mass% and is 70 mass % Or less, the content of the calcium carbonate is 2% by mass or more and 11% by mass or less, the content of the gypsum in terms of anhydride is 5% by mass or more and 10% by mass or less, and A concrete binder having a content of 0.9 times or more of the calcium carbonate content.

According to the invention of (1), the compounding ratio of the additive in the concrete binder for blast furnace cement concrete, specifically, the compounding ratio of calcium carbonate and gypsum was optimized to a specific range unique to the present application. According to this, yet concrete significantly suppressible environmentally friendly and CO ₂ emissions, the blast furnace cement concrete with CO ₂ generated a large amount of normal-weight concrete which is equal to or more than the good Shrinkage Cracking Resistance Can be obtained.

  (2) The concrete binder according to (1), wherein the content of the gypsum in terms of anhydride is 1.0 or more times the content of the calcium carbonate.

  According to the invention of (2), it is possible to further enhance the stability of the effect of improving the shrinkage cracking resistance when the invention of (1) is implemented.

  (3) The concrete binder according to (1), wherein the content of the gypsum in terms of anhydride is 1.6 times or more of the content of the calcium carbonate.

  According to the invention of (3), the effect of improving the shrinkage crack resistance at the time of carrying out the invention of (1) can be made more remarkable, and the stability of the effect expression can be further enhanced.

  (4) The content of the blast furnace slag exceeds 5 mass% and is 30 mass% or less, and the content of the calcium carbonate is 2 mass% or more and 8 mass% or less (1) to (3) The concrete binder according to any one of the above.

  According to the invention of (4), it has been difficult to draw out the merits of the blast furnace cement concrete, and in the concrete equivalent to the blast furnace cement type A, which has not been generally used, the inventions of (1) to (3) It is possible to obtain blast furnace cement concrete having sufficient environmental effects and excellent environmental performance.

  (5) The content of the blast furnace slag exceeds 30 mass% and is 60 mass% or less, and the content of the calcium carbonate is 4 mass% or more and 11 mass% or less (1) to (3) The concrete binder according to any one of the above.

  According to the invention of (5), the effects of the inventions of (1) to (3) are sufficiently expressed in the concrete equivalent to the type B blast furnace cement B that has been conventionally used for blast furnace cement concrete. Blast furnace cement concrete with excellent environmental performance can be obtained.

  (6) A cement composition for blast furnace cement concrete comprising the concrete binder according to any one of (1) to (5), an aggregate, and water.

According to the invention of (6), yet concrete significantly suppressible environmentally friendly and CO ₂ emissions, having a lot plain concrete which is equal to or more than the good Cracking Resistance CO ₂ emissions Blast furnace cement concrete can be obtained.

  (7) A cured blast furnace cement concrete obtained by curing the cement composition according to (6).

According to the invention of (7), blast furnace cement concrete, which is conventionally desirable as an environmentally friendly blast furnace cement concrete, but has a limited application range due to restrictions on physical properties and curing conditions as its hardened body. It can be applied to a wider range of buildings.
(8) A building material arranged along the vertical direction of a building, wherein the building material is formed of the hardened blast furnace cement concrete according to (7).

According to the invention of (8), environmentally-friendly blast furnace cement concrete can be widely used for vertical members such as walls and column members by releasing from construction conditions that particularly require wet curing.
(9) A method for manufacturing a building, comprising using the concrete building material according to (8) as a building material arranged along a vertical direction.

  According to the invention of (9), it can contribute to the manufacture of a building superior to the conventional one in terms of environmental considerations.

  ADVANTAGE OF THE INVENTION According to this invention, the blast furnace cement concrete which has the outstanding shrinkage cracking resistance equivalent to or more than normal concrete can be provided for the blast furnace cement concrete inferior to the shrinkage cracking compared with ordinary cement concrete.

It is drawing which uses for description of the test apparatus of shrinkage crack resistance.

  Hereinafter, each embodiment of a concrete binder for blast furnace cement concrete of the present invention, a cement composition for blast furnace cement concrete using the same, and a cured blast furnace cement concrete obtained by curing the cement composition explain. The present invention is not limited to the following embodiment.

<Concrete binder for blast furnace cement concrete>
The concrete binder for blast furnace cement concrete of the present invention (hereinafter also simply referred to as “binder”) replaces part of Portland cement with blast furnace slag, and further, as an additive, calcium carbonate and gypsum, It is contained at a predetermined ratio. Here, “concrete binder” means cement, cement and cement and blast furnace slag fine powder, fly ash, silica fume, as described in “The Architectural Institute of Japan: Building Construction Standard Specification / Explanation JASS 5, 2009.2”. It is a general term for a mixture of hydraulic inorganic powders such as a powdery substance that combines aggregates and contributes to the development of concrete strength.

  The binder of the present invention comprises Portland cement, blast furnace slag, and other additives including at least calcium carbonate and gypsum. In general, blast furnace cement is classified according to JIS regulations according to the content of blast furnace slag in the binder, type A (over 5% to 30%), type B (over 30% to 60%) and type C (60 3 to 70% or less), the binder of the present invention can be used for any of the above-mentioned types A to C. That is, the content of blast furnace slag in the binder may be in the range of more than 5% and 70% or less. In addition, the binder of the present invention has gypsum and calcium carbonate as essential components as additives, and among these, the content ratio of gypsum with calcium carbonate to be used together is specified. It is characterized by being optimized to the range of

[Additive]
(plaster)
Examples of the gypsum contained in the binder include dihydrate gypsum, hemihydrate gypsum, anhydrous gypsum, and the like, and these may be contained alone or in combination of two or more of the above. May be. The content of these gypsum in the binder is 5% by mass or more and 10% by mass or less, preferably 6% by mass or more and 9% by mass or less in terms of anhydride.

(Calcium carbonate)
As calcium carbonate contained in the binder, for example, industrial calcium carbonate powder, limestone powder, and the like can be used, but it is inexpensive and preferable to use limestone powder. Limestone powder is produced by pulverizing limestone, which is a natural raw material. In addition, as other calcium carbonates, pulverized products such as shells and corals containing calcium carbonate as a main component, or processed products thereof can also be used. The content of these calcium carbonates in the binder is 2% by mass or more and 11% by mass or less, preferably 3% by mass or more and 7% by mass or less.

  In particular, when the content of blast furnace slag in the binder is more than 5% by mass and not more than 30% by mass, that is, the use corresponding to the blast furnace cement type A substantially in the above-mentioned general criteria. When selected, the content of calcium carbonate in the binder is preferably 2% by mass or more and 8% by mass or less.

  In particular, when the content of blast furnace slag in the binder is more than 30% by mass and not more than 60% by mass, that is, the use corresponding to the blast furnace cement type B substantially in the above general criteria is selected. In this case, the content of calcium carbonate is preferably 4% by mass or more and 11% by mass or less.

(Additive composition)
Regarding the content ratio in the binder of gypsum and calcium carbonate, the gypsum content is 0.9 times or more, preferably 1.0 times or more, more preferably 1. 6 times or more. For example, as described above, when the use corresponding to the blast furnace cement type B is substantially selected, when the content of calcium carbonate is adjusted to 4% by mass or more according to the content of the blast furnace slag, accordingly, The gypsum content is also 3.6% by mass (0.9 times that of calcium carbonate) or more. Thus, the composition of the binder of the present invention can be optimized by appropriately adjusting the relative content of gypsum with respect to calcium carbonate to be in the range of the above ratio. And the blast furnace cement concrete hardening body which consists of a cement composition using the binder of such a composition has a shrinkage crack resistance equivalent to or more than normal concrete.

In addition, the content of Al ₂ O ₃ in the following blast furnace slag powder, which is an industrial byproduct (industrial waste), varies. Therefore, when using blast furnace slag powder with a high content of Al ₂ O ₃ as a raw material for blast furnace cement, it is more preferable to finely adjust the blending amount as appropriate, for example, by increasing the blending ratio of calcium carbonate and gypsum.

(Blast furnace slag)
As the blast furnace slag that is a raw material of the binder, powdered blast furnace slag powder can be preferably used. As this blast furnace slag powder, powdered granulated slag obtained by water-cooling and crushing blast furnace slag produced as a by-product when producing pig iron in the blast furnace can be used. The blast furnace slag fine powder 4000 prescribed | regulated by JIS A 6206: 2013 "Blast furnace slag fine powder for concrete" is preferable.

  As described above, the blast furnace cement is classified into three types of A type, B type, and C type according to the content of the blast furnace slag fine powder in the binder according to JIS regulations. However, most of the blast furnace cement concrete that is actually used is only concrete corresponding to type B blast furnace cement B having a blast furnace slag fine powder content of 40 to 45%. Class A equivalent concrete does not sufficiently exhibit the unique advantages of blast furnace cement, and type C concrete has a problem in productivity, such as slow hardening of cement, which prevents the spread of it. On the other hand, if the content of the blast furnace slag in the binding material of the present invention is in the range of more than 5% by mass and 70% by mass or less corresponding to the content ratio range from type A to type C. Good. That is, the binder of the present invention is not only used as a raw material for the above-mentioned concrete corresponding to the blast furnace cement type B, but also concrete equivalent to the blast furnace cement type A or C type, which has been hardly used in the past. Even in the case, the effect can be exhibited.

(Portland cement)
As the Portland cement used together with the blast furnace slag, a conventionally known one can be used without any particular limitation. Specifically, various Portland cements such as ordinary Portland cement, early-strength Portland cement, medium heat Portland cement, and low heat Portland cement can be appropriately used.

<Cement composition for blast furnace cement concrete>
The cement composition for blast furnace cement concrete of the present invention (hereinafter also simply referred to as “cement composition”) is composed of the binder of the present invention, water, fine aggregate, coarse aggregate and admixture. is there. The cement composition of the present invention can be obtained by putting each material containing the binder of the present invention into a mixer and kneading.

  The blending amount of the binder in the cement composition of the present invention (cement internal ratio) is preferably 90% by mass or less, and particularly preferably 5 to 70% by mass. When the blending amount of the cement additive in the cement composition exceeds 90% by mass, there is a possibility that strength development and durability of the obtained cementitious hardened body may be lowered. Thus, according to the cement additive of the present invention and the cement composition containing the cement additive, industrial waste can be used in large quantities.

  The water binder ratio of the cement composition of the present invention will be described. The cement composition of the present invention has a ratio of water to a binder, that is, a water binder ratio of 15 to 60%, preferably 30 to 55%. It is possible to adjust a cement composition having excellent freeze-thaw resistance and fire resistance, and at the same time, a cement composition that solves the problem of neutralization when using a binder with a high content of blast furnace slag fine powder. Can be prepared.

  The adjustment method of the cement composition of this invention is not specifically limited, It can adjust by a well-known method. When adjusting the cement composition of the present invention, additives such as an anti-separation agent, a setting accelerator, a rust inhibitor, a waterproofing agent, and an antiseptic agent are used in combination, as long as the effects of the present invention are not impaired. can do.

<Hardened blast furnace cement concrete>
The hardened blast furnace cement concrete of the present invention is a hardened concrete body obtained by curing the cement composition for blast furnace cement concrete of the present invention.

As described above, conventionally, a widespread use of a hardened blast furnace cement concrete as an environmentally friendly concrete that can contribute to the reduction of CO ₂ generation is desired. Nevertheless, widespread use has been hindered by the fact that shrinkage cracking resistance is inferior to that of ordinary concrete.

  However, by using the concrete binder of the present invention as a cement composition binder, the above-mentioned environment-friendly concrete, but excellent shrinkage cracking that is approximately equal to or better than conventional ordinary concrete. An excellent hardened blast furnace cement concrete having resistance can be obtained.

  The method of curing from the cement composition of the present invention to the hardened blast furnace cement concrete is not particularly limited, and conventional methods can be appropriately employed. This hardened blast furnace cement concrete can be used as a hardened concrete constituting a concrete structure such as a steel pipe concrete member and a concrete pile, as well as a conventional ordinary concrete hardened body.

  Further, the hardened blast furnace cement concrete from the cement composition of the present invention is characterized in that in the hardening process, a wet curing treatment, which is an essential treatment in conventional blast furnace cement concrete, is not necessarily essential. . This is largely different from the fact that conventional blast furnace cement concrete requires a larger amount of water of hydration than ordinary concrete at the time of hardening, so that finishing treatment such as wet curing is essential. The hardened blast furnace cement concrete body of the present invention can be widely used for vertical members arranged along the vertical direction during construction, such as walls and pillar members, by releasing from construction conditions that require wet curing during curing. It became possible.

<Mechanism for suppressing shrinkage cracking>
As described above, the cured blast furnace cement concrete of the present invention that can contribute to the reduction of CO ₂ generation has the above-described excellent shrinkage cracking resistance, unlike the conventional cured blast furnace cement concrete, for the following reason. It is thought to be due to.

In the hydration reaction of a cement composition containing blast furnace cement, Al ₂ O ₃ and ettringite react to produce monosulfate. In conventional cement compositions for blast furnace cement concrete, the formation of monosulfate in the hardened concrete during the curing process is suppressed, and the resulting hardened concrete is prevented from sulfate expansion and is durable (sulfate resistant In order to improve the ratio of the additive to the concrete binder, it is preferable that the calcium carbonate content is higher than the gypsum content.

  However, in order to suppress shrinkage cracking of blast furnace cement concrete, the inventors of the present invention are effective to set the content of gypsum to a content ratio of a predetermined range or more, rather than calcium carbonate. And the content ratio of gypsum to calcium carbonate in the concrete binder was at least 0.9, preferably 1.0 or more, more preferably 1.6 or more.

The reason why such a relatively large amount of gypsum is effective in suppressing shrinkage cracking of blast furnace cement concrete is considered to be as follows. One reason is that the content of gypsum in the binder is relatively large, so that the amount of ettringite can be increased in the early age of the material and self-expanded by the crystal growth pressure. It is because it is because it can suppress the self-contraction at the time. And as another reason, the speed of dissolution of blast furnace slag dominates the reaction of blast furnace slag, so that insoluble anhydrous gypsum that is slow dissolving is suitable for reacting with Al ₂ O ₃ dissolved from blast furnace slag. Is mentioned. It has already been confirmed that anhydrous gypsum suppresses the hydration reaction of blast furnace slag at high temperatures.

  Hereinafter, the present invention will be described in detail with reference to examples. In addition, this invention is not limited to the Example shown below at all.

<Example>
In order to verify the correlation between the amount of calcium carbonate and gypsum added to the binder and the shrinkage cracking resistance of the hardened concrete, the following tests were conducted. The following compressive strength test and free strain test were performed on test specimens made of concrete as shown in Table 1 below. As the material for the concrete binder forming the test body, ordinary Portland cement was used as the cement material in addition to the blast furnace slag fine powder shown in Table 1 (described as blast furnace slag in Table 1). Regarding the amount of ordinary Portland cement added to the binder, by adjusting the amount of ordinary Portland cement added, fine powder of blast furnace slag in the binder (Brain 4230 cm ² / g; product name “Cerement” Co., Ltd.) The amount of ordinary Portland cement was appropriately adjusted so that the content ratio of gypsum (anhydrous gypsum) and calcium carbonate was the ratio (mass%) shown in Table 1, respectively. The amount of blast furnace slag fine powder added in the binder was 20% and 42%, respectively, assuming blast furnace cement type A equivalent and type B equivalent. The gypsum content is the content in terms of anhydride, and the content ratio of gypsum and calcium carbonate is shown in Table 1 as <S> / <CA>.
As for the aggregate to be blended in the cement composition, fine aggregate (1) (mountain sand), fine aggregate (2) (hard sandstone crushed sand), coarse aggregate (hard sandstone crushed stone) are used, and fine aggregate is used. (1) and fine aggregate (2) were in a mass ratio of 8: 2. The fine aggregate was blended in the whole aggregate at a ratio of 46% by volume, and the ratio of water and binder in the cement composition was 50%, and the unit water amount was 175 kg / m ³ .
Further, assuming that no wet curing is performed at the initial stage of curing, the curing conditions are all sealed curing until the material age of 7 days, and air drying curing of RH 60% after the material age of 7 days.
In addition, in order to use as a standard for comparison, the same experiment was conducted as appropriate for ordinary concrete.

(Compressive strength test)
The shape of the test body used for the compressive strength test was φ100 × 200 mm, and a test body was prepared according to JIS A1132, “How to make a test body for concrete strength test”. Immediately after the test specimen was prepared, the seal was cured, and after 7 days of age, the material was air-dried at 60% RH. At the age of 28 days, the compressive strength test was performed according to JIS A 1108 “Concrete compressive strength test method”. The results are shown in Table 1. The evaluation criteria were as follows.
A: 46.1 N / mm ² or more (103% or more of the reference example)
B: 44.7 N / mm ² or more and less than 46.1 N / mm ² C: Less than 44.7 N / mm ²

(Free strain test)
The shape of the specimen used for the free strain test was φ100 × 200 mm, and the free strain of the concrete was continuously measured immediately after placing the concrete with an embedded strain gauge installed at the center of the specimen. Sealing curing immediately after the preparation of the test specimen, and air drying curing of RH 60% after the age of 7 days. The starting point of JIS A 1147 “Concrete setting time test method” was used as the starting point, and the evaluation was made based on the value of free strain at the age of 20 weeks.
The results are shown in Table 1. The evaluation criteria were as follows.
A: 598 μ or less (less than 97% of the reference example)
B: greater than 598μ and less than 616μ C: greater than 616μ

  From the results of Table 1, the hardened blast furnace cement concrete comprising the cement composition for blast furnace cement concrete using the concrete binder of the present invention has a smaller shrinkage and higher strength than ordinary concrete without wet curing. You can see that it is obtained.

(Confirmation of shrinkage crack resistance)
Further, for the purpose of confirming the shrinkage crack resistance of the hardened blast furnace cement concrete of the present invention, the restraint crack test apparatus 100 shown in FIG. The test was carried out using The test conforms to the “Concrete Shrinkage Crack Evaluation Test Method” proposed by the Japan Concrete Institute “Concrete Crack Reduction and Durability Improvement Research Committee Report (2011.9)”. I went. This test is a test for evaluating the age of the generation of shrinkage cracking of concrete caused by restraining the shrinkage of concrete due to drying. The lower the shrinkage cracking resistance, the earlier the cracking occurs. Shrinkage crack resistance was evaluated based on the crack age obtained in this test. In the pass / fail evaluation, the same or higher than normal concrete (reference example) under the same curing condition was evaluated as A, and less than equal as C.
The curing conditions were as follows.
Condition 1: 10 ° C. sealed curing immediately after specimen preparation, 10 ° C., RH 60% air-drying curing after 7 days of age Condition 2: 20 ° C. sealing curing immediately after specimen preparation, 20 ° C. after 7 days of age, RH60% air-drying curing Condition 3: 30 ° C sealed curing immediately after preparation of the test specimen, after 30 days of age, 30 ° C, RH 60% air-drying curing

  From the results in Table 2, the cracked material age of the hardened blast furnace cement concrete of the present invention was larger than that of ordinary concrete under the same curing conditions, and the high shrinkage cracking resistance of the present technology was confirmed.

1 Test section (removal of adhesion)
2A, 2B Fixing section (thread cutting)
3 Strain gauge 10 Restraint crack test body 100 Restraint crack test equipment

Claims (9)

A concrete binder for blast furnace cement concrete,
Contains Portland cement, blast furnace slag, calcium carbonate, and gypsum,
The content of the blast furnace slag is more than 5% by mass and 70% by mass or less,
The calcium carbonate content is 2 mass% or more and 11 mass% or less,
A concrete binder in which the content of the gypsum in terms of anhydride is 5% by mass or more and 10% by mass or less and 0.9 times or more the content of the calcium carbonate.   The concrete binder according to claim 1, wherein the content of the gypsum in terms of anhydride is 1.0 or more times the content of the calcium carbonate.   The concrete binder according to claim 1, wherein the content of the gypsum in terms of anhydride is 1.6 times or more of the content of the calcium carbonate. The content of the blast furnace slag is more than 5% by mass and 30% by mass or less,
The concrete binder according to any one of claims 1 to 3, wherein a content of the calcium carbonate is 2 mass% or more and 8 mass% or less. The content of the blast furnace slag is more than 30% by mass and 60% by mass or less,
The concrete binder according to any one of claims 1 to 3, wherein a content of the calcium carbonate is 4 mass% or more and 11 mass% or less.   A cement composition for blast furnace cement concrete, comprising the concrete binder according to any one of claims 1 to 5, an aggregate, and water.   A cured blast furnace cement concrete obtained by curing the cement composition according to claim 6. Building materials arranged along the vertical direction of the building,
A concrete building material comprising the hardened blast furnace cement concrete according to claim 7.   A method for manufacturing a building, comprising using the concrete building material according to claim 8 as a building material disposed along a vertical direction.

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