JP4643291B2 - Coarse aggregate selection method - Google Patents

Description

  The present invention relates to a method for selecting a coarse aggregate used for concrete, and more particularly to a selection method suitable for selecting a coarse aggregate used for high-strength concrete.

  The compressive strength of concrete is particularly important among the physical properties of hardened concrete, but in general, the estimation is based on the binder-water ratio obtained as a result of trial kneading, that is, the binder paste in the concrete. It is based on the mass ratio of the binding material and water, and the physical properties of the coarse aggregate are not paid much attention.

  As a study focusing on the relationship between the compressive strength of concrete and the coarse aggregate, for example, there is one in Non-Patent Document 1. However, in the case of general concrete where the compressive strength of the mortar part is small compared to the compressive strength of the coarse aggregate, the influence of the coarse aggregate on the compressive strength of the concrete is small, due to the variation in physical properties between the lots of the coarse aggregate Since the influence is not particularly problematic, the physical properties are not strictly examined when selecting coarse aggregates. However, from the need to eliminate low-grade coarse aggregate, for example, as represented by the stipulation of crushed stone and sand for concrete in JIS A5005, a lower limit value for density, an upper limit value for water absorption, etc. The quality of the coarse aggregate is defined by the physical property value of the coarse aggregate itself, and the coarse aggregate that does not satisfy the specified value is not used.

On the other hand, high-strength concrete (for example, with a design standard strength of about 100 N / mm ² or more) that has recently been applied to construction works has a destructive property different from that of ordinary concrete. The effect of coarse aggregate used for high-strength concrete is being reviewed. For example, Non-Patent Document 2 reports the effect of coarse aggregate on the strength of high-strength concrete of 80 N / mm ² or more. According to this, it has been concluded that it is effective to use coarse aggregate having the same degree of rigidity as the mortar matrix in order to increase the strength of concrete.

  Furthermore, in Non-Patent Document 2, compared to a coarse aggregate having an elastic modulus close to that of a mortar matrix, when a coarse aggregate having a larger elastic modulus is used, the strength of the concrete is reduced. It suggests that the stress concentration caused by the difference in rigidity between coarse aggregate and mortar is the cause of concrete compressive failure, and the wear loss of coarse aggregate, 40 ton crushing value, point load strength, and concrete It was said that no significant correlation could be found in the relationship with intensity.

"Fundamental study on coarse aggregate and concrete strength (1)", Architectural Institute of Japan, Proceedings of December 1969, P19-P27 "Developmental research on ultra-high-strength concrete (3)", Abstracts of Annual Conference of Architectural Institute of Japan, October 1990, P495-P496

  There are few quantitative data on the influence of the physical properties of coarse aggregates on the compressive strength of high-strength concrete, and the physical properties of coarse aggregates collected from nature are not easy to handle compared to other industrial products. For this reason, at the time of manufacturing high-strength concrete, there are currently no special provisions for quality control other than the lower limit value of density and the upper limit value of water absorption rate for coarse aggregates.

  However, in order to manage the strength of high-quality high-strength concrete, it is necessary to consider physical properties other than the lower limit value of the density of the coarse aggregate to be mixed into the concrete and the upper limit value of the water absorption rate. On the other hand, in order to smoothly achieve the construction plan, it is necessary to select the coarse aggregate easily. Non-Patent Documents 1 and 2 refer to the relationship between the physical properties of the coarse aggregate and the compressive strength of the concrete, but do not mention how to actually select the coarse aggregate.

  Accordingly, an object of the present invention is to provide a method for easily selecting a coarse aggregate suitable for the compressive strength of the concrete to be produced, particularly the compressive strength of the high-strength concrete.

  According to the first aspect of the present invention, the compressive strength of a concrete specimen prepared for each coarse aggregate having a different Young's modulus is determined by compressing the base mortar specimen prepared by removing the coarse aggregate from the concrete specimen. A preparation process for preparing index data indicating the relationship between the reference index value divided by the strength and the Young's modulus of the coarse aggregate, and the target compressive strength of the concrete to be produced from this concrete, excluding the coarse aggregate An allowable range setting step of setting an allowable range of Young's modulus of the coarse aggregate used for the concrete based on the actual index value divided by the compressive strength of the produced base mortar and the index data; A coarse aggregate selection method comprising: a selection step of selecting a coarse aggregate having a Young's modulus belonging to the allowable range set by the range setting step.

  In this coarse aggregate selection method, the value obtained by dividing the compressive strength of concrete by the compressive strength of base mortar made by removing coarse aggregate from the concrete is used as an index value, and the allowable range of Young's modulus of coarse aggregate is set. By doing so, a coarse aggregate suitable for this can be easily selected according to the compressive strength of the concrete to be produced, particularly the compressive strength of the high-strength concrete. In addition, the index data prepared in the preparation step may be prepared by preparing the concrete specimen and the base mortar specimen during the production of concrete, and may be prepared in the past. You may prepare the said index data of the result of the said test.

  In the first aspect of the present invention, the actual index value may be a value obtained by dividing a value obtained by adding a correction value to the target compression strength by the compression strength of the base mortar.

  By doing this, it is possible to correct the error in the compressive strength between the concrete specimen and the actual concrete, and to select the coarse aggregate necessary to achieve the target concrete compressive strength more accurately.

  In the first aspect of the present invention, the index data is a correlation formula between the reference index value and the Young's modulus of the coarse aggregate, and in the allowable range setting step, the actual index value and the correlation formula Based on the above, the upper limit value of the Young's modulus of the coarse aggregate can be calculated as the allowable range.

  By using the correlation equation, the allowable range can be set more easily.

  In the first aspect of the present invention, in the allowable range setting step, the upper limit value of the Young's modulus is replaced with the absolute dry density or surface dry density of the coarse aggregate, and the replaced value is set as the allowable range as the coarse bone. It can also be set as the upper limit of the absolute dry density or surface dry density of the material.

  Although it is not always easy to measure the Young's modulus of the coarse aggregate, the allowable range is specified by the absolute dryness or surface dry density of the coarse aggregate, which is relatively easy to measure, thereby making it easier and easier to measure the coarse bone. The material can be selected.

  Further, according to the second aspect of the present invention, the compressive strength of the concrete specimen prepared for each coarse aggregate having a different compressive strength is used as the base mortar specimen prepared by removing the coarse aggregate from the concrete specimen. Based on the relationship between the reference index value divided by the compressive strength and the compressive strength of the coarse aggregate, a setting step for setting a lower limit value of the compressive strength of the coarse aggregate used in the concrete to be produced from now on, And a selecting step for selecting a coarse aggregate having a compressive strength equal to or higher than the lower limit set in the setting step.

  In this coarse aggregate selection method, the value obtained by dividing the compressive strength of concrete by the compressive strength of the base mortar made by removing the coarse aggregate from the concrete is used as an index value, and the lower limit value of the compressive strength of the coarse aggregate is set. By doing so, a coarse aggregate suitable for this can be easily selected according to the compressive strength of the concrete to be produced, particularly the compressive strength of the high-strength concrete.

  In the second aspect of the present invention, in the setting step, the lower limit value is replaced with the point load strength of the coarse aggregate, and in the selection step, the coarse aggregate having a point load strength equal to or higher than the replaced point load strength. Can also be selected.

  Although it is not always easy to measure the compressive strength of coarse aggregate, it is easier to select the coarse aggregate by defining the lower limit value based on the point loading strength of the coarse aggregate that is relatively easy to measure. be able to.

  According to the present invention, a coarse aggregate suitable for this can be easily selected according to the compressive strength of the concrete to be produced, particularly the compressive strength of the high-strength concrete.

1. Outline In this embodiment, the value obtained by dividing the compressive strength of concrete by the compressive strength of the base mortar produced by removing the coarse aggregate from the concrete and making it dimensionless is required for the coarse aggregate as an evaluation index value. A range of Young's modulus or compressive strength is defined, and a coarse aggregate corresponding to at least one of them is selected.

2. Test with Specimen In the present embodiment, in selecting a coarse aggregate, a test result using a concrete specimen and a base mortar specimen prepared by removing the coarse aggregate from the concrete specimen is used. Therefore, first, an actual test will be described as an example.

<Coarse aggregate and its physical properties>
In this test, a total of 6 types of coarse aggregates 1 to 6 with different physical properties of 1 type of andesite system, 2 types of hard sandstone system, 2 types of limestone system, and 1 type of quartz schist system are used, and concrete is used for each type of coarse aggregate. A specimen (hereinafter simply referred to as a specimen together with the base mortar specimen) was prepared. FIG. 1 is a diagram showing test results relating to various physical properties (Young's modulus, compressive strength, absolute dry density, point load strength) of the coarse aggregate used for specimen preparation.

The compressive strength test of coarse aggregate was performed in accordance with JIS M 0302 “Test method for compressive strength of rocks” using 6 pieces of φ50 × 100 mm specimens collected from various coarse aggregates by core boring. went. The Young's modulus is a test based on JIS M 0302 and calculated based on JIS A 1149 “Testing Method for Static Elastic Modulus of Concrete”. In the stress-strain curve when a test piece is loaded, the maximum load The secant elastic modulus given as the gradient of the line segment connecting the stress corresponding to 1/3 of the stress and the stress when the longitudinal strain is 50 × 10 ⁻⁶ .

  Here, in this embodiment, when selecting the coarse aggregate, as will be described later, the Young's modulus or the compressive strength is based on at least one of the Young's modulus and the compressive strength. It is a physical property value that is difficult to obtain unless a test is performed using a test piece collected by core boring. However, when selecting coarse aggregates at the stage of actually producing concrete, it is desirable that these can be estimated indirectly through tests that can be performed using coarse aggregates having a maximum size of 20 mm.

  Focusing on the absolute dry density and spot load strength of coarse aggregates as physical property values that can indirectly estimate Young's modulus and compressive strength in tests that can be performed using coarse aggregates with a maximum dimension of 20 mm. Measurement was performed (see FIG. 1).

  2A is a relationship between the absolute dry density and Young's modulus (average value) of each of the coarse aggregates 1 to 6 based on the test results shown in FIG. 1, and FIG. 2B is based on the test results shown in FIG. It is a figure which shows the relationship between the point load strength of each coarse aggregate 1 thru | or 6, and compressive strength (average value). The relationship between the absolute dry density and the Young's modulus and the relationship between the point load strength and the compressive strength were all positively correlated. The former correlation coefficient is 0.84 and the latter correlation coefficient is 0.72, which has a high correlation, and can be used as a physical property value capable of indirectly estimating Young's modulus and compressive strength. I can say that. It is also possible to indirectly estimate the Young's modulus by employing the surface dry density (according to JIS A 1110) instead of the absolute dry density. By adopting these as the physical property values of the coarse aggregate, it is possible to more easily select the coarse aggregate.

<Manufacture of specimen and compressive strength test>
FIG. 3 is a diagram showing the mix of concrete and base mortar used for specimen preparation in this test example. In concrete, the absolute volume of the coarse aggregate was constant (volume ratio 0.36), and the conditions other than the type of coarse aggregate were the same for each water binder ratio. The above-mentioned coarse aggregates 1 to 6 were used as the coarse aggregates, respectively, and a total of 30 preparations were tested with a water binder ratio of 5 levels in the range of 15 to 65%. The base mortar was prepared by removing coarse aggregate from each concrete (the materials used were the same), and a total of 5 preparations were tested. Moreover, in order to make the influence which air quantity has on the compressive strength of concrete and base mortar on the same conditions, it set so that the air quantity in base mortar might become the same level as the air quantity in the mortar which comprises concrete.

  The specimen had a size of Φ100 × 200 mm and was a standard curing (20 ° C water curing) until a predetermined age. The age was 7, 28, and 91 days, and three concrete specimens and three base mortar specimens were prepared for each blending and each age. According to JIS A 1108 “Concrete Compressive Strength Test Method”, a compressive strength test was performed, and the average value of the test results of the three bodies was defined as the compressive strength of the concrete specimen and the base mortar specimen. FIG. 4 shows the compression test results as a relationship between the compressive strength of the base mortar specimen and the compressive strength of the corresponding concrete specimen.

In the range where the compressive strength of the base mortar is 50 N / mm ² or less, the ratio of the compressive strength of the concrete to the compressive strength of the base mortar is distributed in the range of 0.8 to 1.1. Regarding the relationship between the coarse aggregate and the compressive strength of concrete, the knowledge that the compressive strength is increased by mixing coarse aggregate and the knowledge that the compressive strength is reduced are mixed, but this result is consistent with both findings. Yes.

On the other hand, in the range where the compressive strength of the base mortar exceeds 50 N / mm ² , the ratio of the compressive strength of the concrete to the compressive strength of the base mortar is generally distributed in the range of 0.8 to 1.0, and the value is used. Varies depending on coarse aggregate. Therefore, in this embodiment, a value obtained by dividing the compressive strength of the concrete by the compressive strength of the base mortar and making it dimensionless is used as the evaluation index value. The fact that the evaluation index value becomes a large value indicates that a higher strength concrete can be obtained even when the mortar portion is under the same conditions.

<Relationship between evaluation index value and Young's modulus of coarse aggregate>
FIGS. 5A to 5D are diagrams showing the relationship between the evaluation index value and the Young's modulus of the coarse aggregates 1 to 6 by dividing the compressive strength of the base mortar into four regions, and FIG. region of compressive strength ≦ 50 N / mm ² of the base mortar, FIG. 5 (b) 50 N / mm ² <based mortar region of compressive strength ≦ 100 N / mm ^2, and FIG. 5 (c) 100 N / mm ² <base The region of mortar compressive strength ≦ 150 N / mm ² , FIG. 5D shows the region of base mortar compressive strength> 150 N / mm ² , respectively.

  The region shown in FIG. 5A corresponds to a compressive strength region of general concrete, and no significant correlation is found between the evaluation index value and the Young's modulus (correlation coefficient is 0.072). ). On the other hand, in the regions shown in FIGS. 5B to 5D, a negative correlation is observed between the evaluation index value and the Young's modulus (correlation coefficients are 0.67, 0.63, and 0.60 in this order). This indicates that, in high-strength concrete, when the mortar matrix is under the same conditions, the use of coarse aggregate having a low Young's modulus provides a higher-strength concrete. That is, it is effective to use the evaluation index value and the Young's modulus as a reference when selecting the coarse aggregate. Note that the mathematical expressions in FIGS. 5A to 5D show correlation expressions between the evaluation index value and the Young's modulus.

<Relationship between evaluation index value and compressive strength of coarse aggregate>
6A to 6D are diagrams showing the relationship between the evaluation index value and the compressive strength of the coarse aggregates 1 to 6 by dividing the compressive strength of the base mortar into four regions, and FIG. region of compressive strength ≦ 50 N / mm ² of the base mortar, FIG. 6 (b) 50 N / mm ² <areas of compressive strength ≦ 100 N / mm ² base mortar, FIG. 6 (c) 100 N / mm ² <base The region of mortar compressive strength ≦ 150 N / mm ² , FIG. 6D shows the region of base mortar compressive strength> 150 N / mm ² , respectively.

  The overall tendency of the relationship between the evaluation index value and the compressive strength of the coarse aggregate is shown in a portion surrounded by a broken line in the figure. That is, in the area shown in FIG. 6 (b), the evaluation index value of the coarse aggregates 4 and 5 decreases, and subsequently, in the areas shown in FIGS. 6 (c) and 6 (d), the coarse aggregate 3 is reduced. It can be seen that the evaluation index value of the used one is also lowered. That is, it is understood that it is desirable to use a coarse aggregate having a compressive strength sufficiently higher than the target value of the compressive strength of the concrete for high-strength concrete.

3. Coarse Aggregate Selection Method Hereinafter, two types of coarse aggregate selection methods will be described as embodiments of the present invention. The selection of the coarse aggregate desirably satisfies the requirements of both of these two types of selection methods, but may be either one.

<Selection method based on evaluation index value and Young's modulus of coarse aggregate>
-Preparation process Prepare index data showing the relationship between the evaluation index value (referred to as the standard index value) obtained from the test with the specimen and the Young's modulus of the coarse aggregate used in the concrete specimen. The index data is, for example, test data shown in FIGS. 5 (a) to 5 (d). If the correlation equations shown in FIGS. 5 (a) to 5 (d) have been calculated in advance, the index data is Only the correlation equation needs to be prepared, and this becomes index data. In this embodiment, a case where a correlation equation is used will be described. In addition, the index data only needs to be prepared in a range necessary for the target compressive strength (for example, design standard strength) of concrete to be manufactured.

  The test with the specimen need not be performed every time the concrete is manufactured, and it is sufficient to prepare the index data as a result of the test performed in the past in this preparation step.

-Allowable range setting process A specimen (hereinafter referred to as a base mortar sample) of a base mortar prepared by removing coarse aggregate from concrete to be produced (the same material used) is prepared. The base mortar sample is desirably produced under the same conditions as the base mortar specimen in the test using the specimen. For example, the standard aging is used, and the compressive strength at 28 days of age is 1. It is produced by adjusting the cement-water ratio so that the strength is about 1 to 1.3 times. For example, when the target compressive strength of the 28-day age of concrete to be produced is 150 N / mm ² , the blending is determined so that the compressive strength of the 28-day age of the base mortar sample is 180 N / mm ² .

  Next, the compressive strength of the produced base mortar sample is measured. In this case, it is desirable to prepare a plurality of base mortar samples, and the compressive strength is an average value of the measurement results of the compressive strength of each base mortar sample.

Next, an evaluation index value (referred to as an actual index value) is calculated by dividing the target compressive strength of the concrete to be manufactured by the measured compressive strength of the base mortar sample. Here, the concrete that is actually driven has different curing conditions from the specimen, and therefore the compressive strength may be inferior to that of the specimen. Therefore, when calculating the actual index value, it is desirable to calculate the actual index value by dividing the value obtained by adding the correction value to the target compression strength by the compression strength of the base mortar sample in accordance with the provision of the structure correction strength of JASS5. However, when the concrete compressive strength is about 100 N / mm ² , the correction value is often 0.

Next, the allowable range of the Young's modulus of the coarse aggregate used for the concrete is set from the calculated actual index value and the above correlation equation (index data). In the present embodiment, the upper limit value of the Young's modulus is set by substituting the actual index value into the above correlation equation. For example, the 28-day age target compressive strength of concrete to be produced is 150 N / mm ² (correction value is 0 N / mm ² ), and the 28-day age compressive strength of the base mortar sample is 180 N / mm ² . In this case, the correlation equation in FIG.
(Actual index value: 150/180) = 1.3-0.072 x (upper limit of Young's modulus)
(Upper limit value of Young's modulus) = {1.3- (150/180)} / 0.072
≒ 6.48 (× 10 ⁴ N / mm ² )
And

When the absolute dry density of the coarse aggregate to be selected is used as a reference, the calculated upper limit value is replaced with the absolute dry density, and the replaced value is set as the upper limit value of the absolute dry density of the coarse aggregate. In this case, for example, the calculated upper limit value of Young's modulus is substituted into the correlation equation of FIG.
(Upper limit of Young's modulus: 6.48) = -14.35 + 7.79 x (upper limit of absolute dry density)
(Maximum absolute dry density) = (6.48 + 14.35) /7.79
≒ 2.67 (g / cm ³ )
And The same applies when the surface dry density of the coarse aggregate to be selected is used as a reference.

・ Selection process The physical property value of the coarse aggregate to be selected is examined, the coarse aggregate having the physical property value belonging to the allowable range set by the above-described allowable range setting step is selected, and the coarse bone used for the concrete to be produced from now on Use wood. As the physical property value of the coarse aggregate to be selected, any of Young's modulus, absolute dry density, and surface dry density can be used, and the coarse aggregate is selected for each lot within an allowable range according to the type of physical property.

<Selection method based on evaluation index value and compressive strength of coarse aggregate>
・ Lower limit setting process First, prepare index data indicating the relationship between the evaluation index value (referred to as the reference index value) obtained from the test with the specimen and the compressive strength of the coarse aggregate used in the concrete specimen. . The index data is, for example, test data shown in FIGS. 6 (a) to 6 (d). In addition, it is the same as the case of the selection method based on the Young's modulus mentioned above that the test with the specimen need not be performed every time the concrete is manufactured.

  Next, as in the case of the selection method based on the Young's modulus described above, a base mortar specimen (hereinafter referred to as a base mortar sample) prepared by removing coarse aggregate from concrete to be produced (same material used). )) And measure its compressive strength.

The lower limit value of the compressive strength of the coarse aggregate is set such that the coarse aggregate indicating the decrease in the standard index value is excluded by referring to the index data in the strength region including the measured compressive strength of the base mortar sample. For example, when the compressive strength of the base mortar sample is 180 N / mm ² , the data in FIG. In the portion surrounded by the broken line in the same figure, the reference index value is lower than that in the case of FIG. 6 (c) etc., so that the coarse aggregate having a lower compressive strength is excluded. Set the lower limit of compressive strength. It is desirable to set the lower limit value of the compressive strength with a certain margin. For example, in the case of FIG. 6 (d), a clear decrease in the reference index value is confirmed to be approximately 170 N / mm ² or less. However, there is a possibility that the clear reference index value may be lowered in the hatched region. Therefore, the lower limit value of the compressive strength of the coarse aggregate is set to 190 N / mm ² with a margin.

When the point load strength of the coarse aggregate to be selected is used as a reference, the set lower limit value is replaced with the point load strength, and the replaced value is set as the lower limit value of the coarse aggregate point load strength. In this case, for example, the lower limit value of the compressive strength is substituted into the correlation equation in FIG.
(Lower limit of compressive strength: 190) = 10.89 + 9.15 x (Lower limit of point load strength)
(Lower limit of point load strength) = (190-10.89) /9.15
≒ 19.6 (N / mm ² )
And

・ Selection process Check the physical property value of the coarse aggregate to be selected, select a coarse aggregate with a physical property value that is equal to or higher than the lower limit set by the setting process described above, and use the coarse aggregate to be used for concrete to be manufactured To do. Either the compressive strength or the point load strength can be used as the physical property value of the coarse aggregate to be selected, and the coarse aggregate is selected for each lot with a lower limit value corresponding to the type of physical property.

It is a figure which shows the kind of coarse aggregate used for the concrete specimen and the base mortar specimen, and the test result of the physical property. (A) is the relationship between the absolute dry density (average value of 2 points) and Young's modulus (average value of 3 points) of each of the coarse aggregates 1 to 6 based on the test results shown in FIG. It is a figure which shows the relationship between the point load strength (average value of 30 points) and compressive strength (average value of 6 points) of each coarse aggregate 1 to 6 based on the test results shown in FIG. It is a figure which shows mixing | blending of the concrete specimen used for the test, and a base mortar specimen. The compression test result is represented by the relationship between the compressive strength of the base mortar specimen and the compressive strength of the corresponding concrete specimen. (A) thru | or (d) is the figure which divided | segmented the compressive strength of the base mortar into four area | regions, and showed the relationship between the evaluation index value and the Young's modulus of the coarse aggregates 1-6. (A) thru | or (d) is the figure which divided | segmented the compressive strength of the base mortar into four area | regions, and showed the relationship between the evaluation index value and the compressive strength of the coarse aggregates 1-6.

Claims (6)

The reference index value obtained by dividing the compressive strength of the concrete specimen prepared for each coarse aggregate having a different Young's modulus by the compressive strength of the base mortar specimen prepared by removing the coarse aggregate from the concrete specimen, A preparation step of preparing index data indicating a relationship between the Young's modulus of the coarse aggregate,
Based on the actual index value obtained by dividing the target compressive strength of the concrete to be produced by the compressive strength of the base mortar produced by removing coarse aggregate from the concrete, and the index data, the rough compressive strength used for the concrete is used. An allowable range setting step for setting an allowable range of Young's modulus of the aggregate;
A selection step of selecting a coarse aggregate having a Young's modulus belonging to the allowable range set by the allowable range setting step;
A coarse aggregate selection method comprising: The actual index value is
The coarse aggregate selection method according to claim 1, wherein a value obtained by adding a correction value to the target compression strength is divided by the compression strength of the base mortar. The index data is a correlation formula between the reference index value and the Young's modulus of the coarse aggregate,
In the allowable range setting step,
The coarse aggregate selection method according to claim 1 or 2, wherein an upper limit value of Young's modulus of the coarse aggregate is calculated as the allowable range based on the actual index value and the correlation formula. In the allowable range setting step,
The upper limit value of Young's modulus is replaced with the absolute dry density or surface dry density of the coarse aggregate, and as the allowable range, the replaced value is set as the upper limit value of the absolute dry density or surface dry density of the coarse aggregate. The coarse aggregate selection method according to claim 3. The standard index value obtained by dividing the compressive strength of the concrete specimens prepared for each coarse aggregate having different compressive strengths by the compressive strength of the base mortar specimen prepared by removing the coarse aggregates from the concrete specimens, and Based on the relationship between the compressive strength of the coarse aggregate, and a setting step for setting a lower limit value of the compressive strength of the coarse aggregate used in the concrete to be produced from now on,
A selection step of selecting a coarse aggregate having a compressive strength equal to or higher than the lower limit set by the setting step;
A coarse aggregate selection method comprising: In the setting step,
Replace the lower limit with the point load strength of coarse aggregate,
In the selection process,
6. The coarse aggregate selection method according to claim 5, wherein a coarse aggregate having a point load strength equal to or higher than the replaced point load strength is selected.

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