JP2019001694A - Method for producing portland blast-furnace slag cement type a concrete, and concrete structure - Google Patents

Abstract

To produce a Portland blast-furnace slag cement type A concrete easily without constructing a single-purpose assembly line for a Portland blast-furnace slag cement type A.SOLUTION: A Portland blast-furnace slag cement type A concrete is produced in which the mass ratio of a blast furnace slag to a mixture of a Portland cement and a Portland blast-furnace slag cement type B is more than 5% and 30% or less, by mixing the Portland cement, the Portland blast-furnace slag cement type B, water, and an aggregate.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a method for producing concrete corresponding to blast furnace cement type A and a concrete structure formed from the concrete.

  Examples of the cement include Portland cement (for example, ordinary Portland cement) and blast furnace cement. Portland cement is the most typical type of cement obtained by adding gypsum to a fired mixture of limestone and clay. Blast furnace cement is a cement made by mixing blast furnace slag with Portland cement and has low heat generation due to hydration and high durability. Blast furnace cement is described in Patent Document 1, for example.

  As blast furnace cement, there are blast furnace cement type A, blast furnace cement type B and blast furnace cement type C. In the blast furnace cement type A, the mass ratio of blast furnace slag exceeds 5% and is 30% or less, in the blast furnace cement type B, the mass ratio of blast furnace slag exceeds 30% and is 60% or less, and in the blast furnace cement type C, The mass ratio of blast furnace slag exceeds 60% and is 70% or less.

Japanese Patent Laid-Open No. 3-115144

  Most of the blast furnace cements in the market are blast furnace cement type B. Blast furnace cement type B is often used for civil engineering (for example, construction of tunnels, dams, bridges, harbors, etc.).

  On the other hand, blast furnace cement type A is hardly distributed in the market and is difficult to obtain. However, it may be desired to use blast furnace cement type A for the formation of concrete structures. As such concrete structures using blast furnace cement type A, there are underground structures located below the ground surface and upper structures located above the ground surface. The underground structure is, for example, a concrete pile (pile foundation) provided in the ground for building a building.

  In this regard, since the blast furnace cement type A is hardly distributed in the market as described above, it is conceivable to construct a production line for the blast furnace cement type A. However, when the demand for blast furnace cement type A is expected to be small, it is not realistic to newly construct a dedicated production line for blast furnace cement type A.

  Accordingly, an object of the present invention is to provide a method capable of easily producing concrete equivalent to the blast furnace cement type A without constructing a dedicated production line for the blast furnace cement type A, and a concrete structure using the concrete produced by this method. Is to provide.

  In order to achieve the above object, according to the present invention, by mixing Portland cement, Blast Furnace Cement B, water and aggregate, the mass ratio of blast furnace slag to the combined Portland Cement and Blast Furnace Cement B is 5 A method for producing concrete equivalent to blast furnace cement type A is provided, which produces concrete equivalent to blast furnace cement type A that exceeds 30% and is 30% or less.

  Moreover, according to this invention, the concrete structure formed from the concrete equivalent to the blast furnace cement A class manufactured by the above-mentioned manufacturing method is provided.

  According to the above-described present invention, Portland cement and blast furnace cement type B are mixed to produce concrete equivalent to blast furnace cement type A. Therefore, it is possible to easily manufacture concrete equivalent to the blast furnace cement A type without constructing a production line for manufacturing the blast furnace cement A type from scratch.

It is explanatory drawing of the manufacturing method of concrete by embodiment of this invention. An example of the concrete structure by embodiment of this invention is shown.

  Embodiments of the present invention will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the common part in each figure, and the overlapping description is abbreviate | omitted.

(Production method)
FIG. 1 is an explanatory diagram of a method for producing concrete according to an embodiment of the present invention. In this production method, Portland cement, blast furnace cement type B, water, aggregate (fine aggregate and coarse aggregate), and admixture (chemical admixture) are mixed to prepare ready-mixed concrete corresponding to blast furnace cement type A. To manufacture. Since the admixture is added as necessary, it may not be used in the production of the ready-mixed concrete (the same applies hereinafter). The ready-mixed concrete manufactured in this way is hereinafter referred to as Class A equivalent concrete. In the type A equivalent concrete, the mass ratio of blast furnace slag to only Portland cement and type B blast furnace cement B (excluding water, aggregate, and admixture) exceeds 5% and is 30% or less. In the present application, the mass ratio of blast furnace slag is the blast furnace contained in the target cement with respect to the total mass (excluding water and aggregate) of the target cement (that is, only Portland cement and blast furnace cement B in raw concrete). It is the ratio of the mass of slag (the same applies below). Further, in the present application, assuming that a and b are numerical values, the range of “a% to b%” includes “a%” when the content “the mass ratio is a% to b%” is described. However, it does not need to be included, and may or may not include b%.

  As described above, the Portland cement is a cement obtained by adding gypsum to a baked mixture of limestone, clay, and the like to form a powder. In this embodiment, the Portland cement may be, for example, ordinary Portland cement, but may be other Portland cement.

Blast furnace cement is a cement made by mixing blast furnace slag with Portland cement. Blast furnace slag is blast furnace slag fine powder obtained by pulverizing molten slag produced as a by-product from a blast furnace (blast furnace) in an ironworks. In the present application, the blast furnace cement type A and the blast furnace cement type B may be those defined in the Japanese Industrial Standard JIS R5211, as shown in (1) and (2) below.
(1) The mass ratio of the blast furnace slag in the blast furnace cement type A exceeds 5% and is 30% or less.
(2) The mass ratio of the blast furnace slag in the blast furnace cement type B exceeds 30% and is 60% or less.

  In FIG. 1, the method for producing type A equivalent concrete includes steps S1 to S3. In step S1, Portland cement is manufactured. In step S2, blast furnace cement type B is produced. In step S3, the Portland cement manufactured in step S1, the blast furnace cement type B manufactured in step S2, water, aggregate and admixture are mixed with each other to produce type A equivalent concrete.

  Steps S1 and S2 are performed by the first and second cement manufacturers, respectively. Step S3 is performed by a concrete manufacturer. In addition, the cement manufacturer who performs step S1 may be different from the cement manufacturer who performs step S2.

Step S1 includes steps S11 to S13.
Step S11 is a raw material process. In step S11, a plurality of types of raw materials of Portland cement are pulverized and mixed together to produce a mixed raw material. These plural types of raw materials may mainly contain limestone, clay, silica, and iron oxide.
Step S12 is a baking process. In step S12, the clinker is manufactured by baking the mixed raw material manufactured in step S11 at a high temperature of about 1500 ° C., for example. Thereafter, in step S12, the clinker is rapidly cooled.
Step S13 is a finishing process. In Step S13, Portland cement is manufactured by pulverizing the clinker manufactured in Step S12, adding gypsum or gypsum and a mixture to the clinker, and further crushing the mixture of clinker and gypsum. The mixed material added to the clinker together with gypsum is, for example, blast furnace slag, fly ash, or siliceous mixed material.

Step S2 has steps S21 to S23.
In step S21, Portland cement is prepared.
In step S22, blast furnace slag is prepared. For example, blast furnace slag obtained by pulverizing granulated slag which has been rapidly cooled by jetting water into molten slag generated from a blast furnace at an ironworks is prepared.
In step S23, the blast furnace slag prepared in step S22 is added to the Portland cement prepared in step S21, and these are mixed by a mixer. Thereby, the blast furnace cement B type is manufactured.

In Step S3, Portland cement manufactured in Step S1, blast furnace cement manufactured in Step S2 (Blast Furnace Cement B), water, aggregate, and admixture are mixed with each other to prepare ready-mixed concrete. The mass ratio of the blast furnace slag in the above-mentioned target cement is set to be more than 5% and not more than 30%. That is, the said ready-mixed concrete is manufactured as A class equivalent concrete by step S3.
In step S3, the mixing amount of Portland cement and blast furnace cement B is adjusted in the course of producing ready-mixed concrete by kneading Portland cement, blast furnace cement B, water, aggregate and admixture. By this adjustment, a Class A equivalent concrete is manufactured.

(Adjustment of mixing ratio)
In this embodiment, in step S3, the mass proportion of the blast furnace slag in the type A equivalent concrete is adjusted to a desired value or a desired range by adjusting the mass proportion of Portland cement and blast furnace cement type B mixed together. . Here, the desired range is, for example, 8% to 13%, 13% to 18%, or 18% to 23%.

The mass ratio of blast furnace slag in the portland cement in circulation is 0% to 5% or less.
Moreover, the mass ratio of the blast furnace slag in many blast furnace cement types B currently distributed is 40% to 45% or less. That is, blast furnace cement type B in which the mass ratio of blast furnace slag is 40% to 45% is sold.

  Correspondingly, in the examples, it is known that the mass ratio of blast furnace slag in the Portland cement used in step S3 is 0% to 5%, but which value is 0% to 5%? Although it is known that the mass ratio of blast furnace slag in the blast furnace cement type B used in step S3 is 40% to 45%, which value is 40% to 45%? It is assumed that identification is difficult. Under this assumption, the mass proportions of Portland cement and blast furnace cement mixed together in step S3 may be determined according to the following Table 1.

According to Table 1, step S3 can be performed as follows.
In the case of producing type A equivalent concrete (concrete equivalent to type B blast furnace cement) in which the mass ratio of blast furnace slag is 8% to 13%, the mass ratio of Portland cement and type B blast furnace cement B mixed together is set to 80%. 0: 20.0.
In the case of producing Class A equivalent concrete in which the mass ratio of blast furnace slag is 13% to 18%, the mass ratio of Portland cement and Class B blast furnace cement mixed together is set to 67.5: 32.5.
When producing a Class A equivalent concrete in which the mass ratio of blast furnace slag is 18% to 23%, the mass ratio of Portland cement and Type B blast furnace cement B mixed together is set to 55.0: 45.0.

  In the above-mentioned premise, when it is sufficient to produce Class A equivalent concrete in which the mass ratio of blast furnace slag is 8% to 23%, all of Portland cement and Class B blast furnace cement to be mixed with each other in Step S3 according to Table 1. What is necessary is just to make mass ratio of this blast furnace cement B type with respect to mass (total mass) 20.0%-45.0%.

(Effects of the embodiment),
In Step S3 described above, Portland cement and blast furnace cement type B are mixed to produce type A equivalent concrete (concrete corresponding to blast furnace cement type A). Therefore, without building a dedicated production line for blast furnace cement type A (that is, a facility that performs a raw material process, a firing process, a finishing process, and a process for mixing Portland cement obtained in the finishing process with blast furnace slag), Portland cement And blast furnace cement type B can be mixed to easily produce type A equivalent concrete.

  Moreover, the mass ratio of the blast furnace slag in the type A equivalent concrete can be easily adjusted to a desired value or range by adjusting the mixing ratio of the Portland cement and the blast furnace cement type B mixed in step S3.

  By mixing the Portland cement and blast furnace cement type B manufactured by the cement manufacturer with water, aggregate and admixture, the concrete manufacturer can manufacture type A equivalent concrete. Thus, the concrete manufacturer can easily manufacture concrete equivalent to the blast furnace cement A type by purchasing the Portland cement and the blast furnace cement type B manufactured by the cement manufacturer and mixing them. Therefore, it is possible to easily manufacture the type A equivalent concrete.

(Concrete structure)
Concrete structures that can be formed from the type A equivalent concrete manufactured by the manufacturing method according to the above-described embodiment include an underground structure positioned below the ground surface and an upper structure positioned above the ground surface. . The concrete structure is obtained by solidifying Class A equivalent concrete. FIG. 2 shows an example of the concrete structure.

  In the example of FIG. 2, the concrete structure 10 is a concrete pile (that is, a foundation pile) that is provided inside the ground on which the building is built and supports the building. This concrete pile may be a precast concrete pile or a cast-in-place concrete pile. Moreover, in FIG. 2, although the concrete pile is a support pile in which the lower end part is located in the support layer in the ground, you may be used as another kind of pile (for example, friction pile).

  The present invention is not limited to the above-described embodiments, and various changes can be made within the scope of the technical idea of the present invention.

10 Concrete structures

Claims (7)

  By mixing Portland cement, blast furnace cement type B, water and aggregate, the mass ratio of blast furnace slag to Portland cement and blast furnace cement type B combined is over 5% and equal to or less than 30% A method of producing concrete equivalent to blast furnace cement type A, which produces a concrete of the above type.   The manufacture of concrete equivalent to blast furnace cement type A according to claim 1, wherein the mass ratio is adjusted to a desired value or range by adjusting the mass ratio of the Portland cement and the blast furnace cement type B mixed together. Method.   The method for producing concrete corresponding to blast furnace cement type A according to claim 2, wherein the desired range is 8% to 13%, 13% to 18%, or 18% to 23%. The mass ratio of the blast furnace slag of the Portland cement to the total mass of the Portland cement is 0% to 5%, and the mass ratio of the blast furnace slag of the type B blast furnace cement B to the total mass of the type B blast furnace cement is 40%. If it is ~ 45%,
By setting the mass ratio of the Portland cement and the blast furnace cement type B to be mixed with each other to 80.0: 20.0, concrete corresponding to the blast furnace cement type A in which the mass ratio of blast furnace slag is 8% to 13% is obtained. Manufacture and
By setting the mass ratio of the Portland cement and the blast furnace cement type B to be mixed to each other to 67.5: 32.5, concrete corresponding to the blast furnace cement type A in which the mass ratio of blast furnace slag is 13% to 18% is obtained. Manufacture and
By setting the mass ratio of the Portland cement and the blast furnace cement type B to be mixed with each other to 55.0: 45.0, concrete corresponding to the blast furnace cement type A in which the mass ratio of blast furnace slag is 18% to 23% is obtained. The manufacturing method of the concrete equivalent to the blast furnace cement A class of Claim 1 manufactured. The mass ratio of the blast furnace slag of the Portland cement to the total mass of the Portland cement is 0% to 5%, and the mass ratio of the blast furnace slag of the type B blast furnace cement B to the total mass of the type B blast furnace cement is 40%. If it is ~ 45%,
2. The production of concrete equivalent to blast furnace cement type A according to claim 1, wherein a mass ratio of the blast furnace cement type B to a total mass of the Portland cement and the blast furnace cement type B mixed with each other is 8% to 23%. Method.   The concrete structure formed from the concrete equivalent to the blast furnace cement A class manufactured by the manufacturing method as described in any one of Claims 1-5.   The concrete structure according to claim 6, wherein the concrete structure is a concrete pile provided inside a ground for building a building to support the building.

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