JP2016125833A - Fluidity evaluation method of fly ash, high fluidity fly ash, and fly ash mixed cement - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fluidity evaluation method of fly ash capable of easily and accurately evaluating the propriety as high fluidity fly ash.SOLUTION: The fluidity evaluation method of fly ash of the present invention includes a method or the like of evaluating the fluidity of the fly ash on the basis of the area circularity of fly ash particles and the projection area of the fly ash particles. The high fluidity fly ash of the present invention is fly ash that has been evaluated as the high fluidity fly ash using the fluidity evaluation method. The fly ash mixed cement of the present invention is cement produced by mixing cement and the high fluidity fly ash.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a fly ash fluidity evaluation method that can easily evaluate fly ash that improves the fluidity of mortar and concrete (hereinafter referred to as “high fluidity fly ash”). The present invention relates to an evaluated high fluidity fly ash and a cement obtained by mixing the high fluidity fly ash and cement.

  The quality standard of fly ash for concrete, JIS A 6201 “Fly ash for concrete” affects the fineness of fly ash, the flow value ratio of mortar containing the fly ash, and the compatibility with various concrete admixtures. The fly ash is classified into four types, I type to IV type, using ignition loss as an index to replace the amount of unburned carbon. And in the “commentary” of the JIS, standard fly ash is classified as type II.

  Originally, fly ash is a spherical fine particle. Therefore, when used in concrete or the like, it has been considered that the fluidity of concrete or the like is improved by the ball bearing action, and the unit water amount is reduced. However, even with fly ash that satisfies Class II standards, the fluidity of the concrete may not improve, and new fluidity management items for fly ash that can correctly manage the fluidity of the concrete are required.

  Under such circumstances, in Patent Document 1, a flow test is performed using a cement paste prepared by changing the content of the admixture for concrete by three or more types, and the quality evaluation of fly ash for evaluating the fluidity from the test result Proposed method. However, the quality evaluation method is a method of replacing the trial kneading of concrete with a cement paste flow using the content of the admixture as an index, and does not provide a new fluidity management item for fly ash.

JP 2012-194113 A

Therefore, the present invention can easily and accurately evaluate whether or not the fluidity of concrete or the like is improved when fly ash is used for concrete and mortar or the like without actually measuring the flow as described above. An object of the present invention is to provide a method for evaluating the fluidity of fly ash.
In the present invention, the fluidity of concrete, mortar, and cement paste containing fly ash is simply referred to as fly ash fluidity.

  As a result of intensive studies on the method for evaluating the flowability of fly ash, the present inventor has found that the flowability of fly ash can be evaluated based on the area circularity of the fly ash particles, the projected area, and the like, thereby completing the present invention.

That is, the present invention is a method for evaluating the fluidity of fly ash having the following configuration.
[1] A method for evaluating the fluidity of fly ash, wherein the fluidity of fly ash is evaluated based on the circularity of the fly ash particles and the projected area of the fly ash particles.
[2] A fly ash in which the ratio of the number of fly ash particles having the area circularity of 0.5 or more and the projected area of 100 μm ² or less to the total number of fly ash particles measured is less than 90%. The method for evaluating fluidity of fly ash according to [1], wherein the fluidity is evaluated as high fluidity fly ash.
[3] The ratio of the number of fly ash particles having an area circularity of 0.5 or more and a projected area of fly ash particles of 100 μm ² or less to the total number of fly ash particles measured, A method for evaluating the fluidity of fly ash, wherein the fluidity of fly ash is evaluated based on the dispersion of the area circularity of ash particles.
[4] The ratio of the number of fly ash particles having the area circularity of 0.5 or more and the projected area of 100 μm ² or less to the total number of fly ash particles measured is less than 99%, and The fly ash fluidity evaluation method according to [3], wherein fly ash having an integrated value of the area circularity dispersion of 0.01 or more is evaluated as high fluidity fly ash.
[5] A high fluidity fly ash composed of fly ash evaluated as a high fluidity fly ash using the fly ash fluidity evaluation method according to any one of [1] to [4].
[6] A fly ash mixed cement obtained by mixing cement and the high fluidity fly ash according to [5].

  According to the fly ash fluidity evaluation method of the present invention, the suitability as a high fluidity fly ash can be evaluated easily and with high accuracy.

It is the figure which showed distribution (black part) of fly ash particle | grains A-H on the coordinate whose vertical axis | shaft is the area circularity of a fly ash particle, and a horizontal axis is a projection area of a fly ash particle. It is the graph which showed the curve showing dispersion | distribution of the area circularity of fly ash particle | grains A-H on the coordinate whose vertical axis | shaft is a dispersion | distribution of the area circularity degree of fly ash particle | grains, and a horizontal axis | shaft is a projection area of fly ash.

    Hereinafter, the present invention will be described in detail in the order of fly ash fluidity evaluation method, high fluidity fly ash, and fly ash mixed cement.

1. Fluidity evaluation method of fly ash (1) Area circularity and projected area of fly ash particles First, explanation will be given on the fluidity evaluation method of fly ash based on the area circularity of fly ash particles and the projected area of fly ash particles. To do.
The area circularity of fly ash particles is (4π × projected area of fly ash particles) / (square of the length of the projection of fly ash particles), the closer the shape of fly ash particles to a sphere, The area circularity approaches 1.
The projected area of fly ash particles means the area of the shadow of the particles reflected on the lower plane when a parallel light beam is projected onto the particles from directly above. The length of is the circumference of the shadow of the particle reflected on the lower plane when a parallel light beam is projected onto the particle from directly above.

  The method for measuring the projected area of fly ash particles and the length around the projection of fly ash particles is, for example, by placing a preparation in which the fly ash particles to be evaluated are dispersed on an optical microscope, This is done using a distribution measuring device. Further, it is preferable to use an image type particle size distribution measuring device equipped with a dry classifier because a still image in which each fly ash particle is dispersed can be obtained. The number of particles used for the measurement is preferably 5,000 or more, more preferably 10,000 or more, still more preferably 20,000 or more, and particularly preferably 50,000 or more.

The method for evaluating the flowability of fly ash based on the area circularity of fly ash particles and the projected area of fly ash particles is preferably such that the area circularity is 0.5 or more with respect to the total number of fly ash particles measured and This is a method for evaluating fly ash having a ratio of the number of fly ash particles having a projected area of 100 μm ² or less (hereinafter referred to as “specific particle ratio”) of less than 90% as high fluidity fly ash. According to this method, the suitability as a high fluidity fly ash can be easily evaluated.
The lower limit of the specific particle ratio is 70%. When the specific particle ratio is less than 70%, there is a risk that the strength development property of concrete and the like is lowered.

(2) Dispersion of area circularity of fly ash particles Next, a fly ash fluidity evaluation method based on the specific particle ratio and the dispersion of the fly ash particle area circularity will be described.
FIG. 1 shows the distribution of fly ash particles on the coordinates where the vertical axis represents the area circularity of the fly ash particles and the horizontal axis represents the projected area of the fly ash particles. Then, taking the axis of the frequency (that is, the number of particles) which is the third axis perpendicular to the vertical axis and the horizontal axis in FIG. 1, the dispersion was obtained from the frequency distribution of the fly ash particles for each projected area of the fly ash particles. . FIG. 2 is a graph showing a curve representing the dispersion on coordinates where the dispersion is on the vertical axis and the projected area of fly ash particles is on the horizontal axis.

In the fly ash fluidity evaluation method based on the specific particle ratio and the dispersion of the area circularity of the fly ash particles, preferably, the specific particle ratio is less than 99% and the integrated value of the dispersion of the area circularity is 0.00. This is a method for evaluating a fly ash of 01 or more as a high fluidity fly ash. According to this method, the suitability as a high fluidity fly ash can be evaluated relatively easily and with high accuracy. In the method, the specific particle ratio is more preferably 95% or less, and particularly preferably 90% or less. The integrated value of the variance of the area circularity is more preferably 0.014 or more.
The integrated value of the variance of the area circularity is a value obtained by integrating a curve showing the variance of the area circularity in a region where the projected area is 1 μm ² or less, and can be obtained by numerical integration such as a trapezoidal formula.

2. High fluidity fly ash and fly ash mixed cement The high fluidity fly ash of the present invention is obtained by using the fly ash fluidity evaluation method according to any one of [1] to [4] above. It consists of fly ash evaluated as ash.
The fly ash mixed cement of the present invention is a mixed cement obtained by mixing cement and the high fluidity fly ash. The cement is not particularly limited, and is at least one selected from the group consisting of ordinary Portland cement, early-strength Portland cement, moderately hot Portland cement, low heat Portland cement, blast furnace cement, silica cement, and ecocement. Moreover, a ball mill, a Henschel mixer, etc. can be used for the mixing apparatus of the said cement and the said high fluidity fly ash.

EXAMPLES Hereinafter, although an Example demonstrates this invention, this invention is not limited to these Examples.
1. Materials used Fly ash A to H having different production areas and lots shown in Table 1 were used.

2. Measurement of area circularity of fly ash particles, and dispersion of area circularity After each 50,000 particles of fly ash A to H were targeted, each particle was dispersed using a dry classifier, Images of fly ash particles were taken and analyzed with an optical microscope. “Morphology G3” manufactured by Malvern was used for taking and analyzing the images. FIG. 1 shows the distribution of fly ash particles in which fly ash A to H has an area circularity of 0.5 or more and a projected area of 100 μm ² or less. Further, Table 2 shows the ratio of fly ash particles (specific particle ratio (%)) in which the area circularity in 50,000 grains is 0.5 or more and the projected area is 100 μm ² or less.

Further, the variance of the area circularity was calculated from the digital data of the photographed image using statistical processing software, and the integration of the variance in the region having the projected area of 1 μm ² was obtained by approximating with the trapezoidal formula. FIG. 2 shows a graph of the obtained dispersion value (the vertical axis is the variance of the area circularity and the horizontal axis is the projected area). In addition, Table 2 shows the integrated dispersion of the area circularity in the region where the projected area is 1 μm ² or less.

3. Measurement of fluidity of mortar containing fly ash A to H In order to confirm the fluidity of fly ash A to H, a flow test was performed using the mortar containing the fly ash. Specifically, 25% by mass of fly ash A to H is mixed with 75% by mass of ordinary Portland cement, and then mortar is prepared according to JIS R 5201 “Cement physical test method”, and flow test is performed. Went. The obtained flow values are shown in Table 2.

As shown in Table 2,
(1) In the fly ash fluidity evaluation method based on the area circularity of fly ash particles and the projected area of fly ash particles, fly ash A, C, D, and H having a specific particle ratio of less than 90% are fly ash particles. The fluidity is improved compared to mortar that does not use ash. Therefore, a fly ash having a specific particle ratio of less than 90% can be evaluated as a high fluidity fly ash.
Also,
(2) In the fly ash fluidity evaluation method based on the specific particle ratio and the dispersion of the area circularity of the fly ash particles, the specific particle ratio is less than 99% and the integrated value of the dispersion of the area circularity is 0.01 or more. Fly ash A, C, D, E, and H have improved flowability over mortars that do not use fly ash. Therefore, fly ash having a specific particle ratio of less than 99% and an integrated value of dispersion of area circularity of 0.01 or more can be evaluated as high fluidity fly ash.
Note that the fly ash fluidity evaluation method based on the specific particle ratio and the dispersion of the circularity of the area of the fly ash particles is a fly ash that was not evaluated as a high fluidity fly ash by the above-mentioned method of evaluating only from the specific particle ratio. E can be evaluated as a high fluidity fly ash, and the accuracy of evaluation is higher than the method of evaluating only from the specific particle ratio.

Claims (6)

  A method for evaluating the flowability of fly ash, wherein the flowability of fly ash is evaluated based on the circularity of fly ash particles and the projected area of fly ash particles. Fly ash with a ratio of the circularity of the area of 0.5 or more and the projected area of 100 μm ² or less to the total number of fly ash particles measured is less than 90%. The method for evaluating the fluidity of fly ash according to claim 1, wherein the fly ash is evaluated as a soluble fly ash. The ratio of the number of fly ash particles in which the area circularity of the fly ash particles is 0.5 or more and the projected area of the fly ash particles is 100 μm ² or less with respect to the total number of fly ash particles measured, A method for evaluating the fluidity of fly ash, wherein the fluidity of fly ash is evaluated based on the dispersion of area circularity. The ratio of the number of particles of fly ash particles having the area circularity of 0.5 or more and the projected area of 100 μm ² or less to the total number of particles of fly ash particles measured is less than 99%, and the area circle The fly ash fluidity evaluation method according to claim 3, wherein fly ash having an integrated value of degree of dispersion of 0.01 or more is evaluated as high fluidity fly ash.   The high fluidity fly ash which consists of a fly ash evaluated as a high fluidity fly ash using the fluidity evaluation method of the fly ash of any one of Claims 1-4. A fly ash mixed cement obtained by mixing cement and the high fluidity fly ash according to claim 5.

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